RU2371233C2 - Device for treatment of drinking water - Google Patents

Abstract

FIELD: technological processes, filters.

SUBSTANCE: invention is related to the field of water preparation, namely to devices for water treatment, and may be used for treatment of drinking water from natural admixtures dissolved in it in industrial and household-domestic water supply. Device comprises body with nozzles of treated water supply and clean water discharge, loose multilayer filter with various grain size of layers and with the facility of filter regeneration, and nozzle of flushing waters drain. Nozzle of water supply is connected to body through aerator. In lower part of body there are nozzles of clean water discharge, flushing waters supply and drain to sewage. Upper layer of filter is made of schungite, the second layer - of quartz sand or anthracite, and the third layer is made of crushed stone. A layer of magnesium dioxide is arranged on surface of charge particles. Drainage system is provided in the third layer of grained charge.

EFFECT: reduction of overall opacity of water by removal of bivalent iron compounds, hydrogen sulfide, heavy metals and humates from it.

12 cl, 2 dwg

Description

The invention relates to the field of water treatment, and in particular to the field of water purification devices, and can be used to purify drinking water from natural impurities dissolved in it in industrial and domestic water supply.

Known (US patent 3497068) is a filter for water purification, comprising a housing with inlet and outlet pipes and layers of coarse-grained (crushed stone) and fine-grained (sand) filter media located in the casing. At the same time, the indicated filter is recommended to be washed periodically by supplying flushing water to the outlet of the purified water.

A disadvantage of the known filter should be recognized as the poor quality of the regeneration of the load during washing, as well as the removal of the filter load from the housing during backwashing.

The development of the design of this filter can be recognized (SU, copyright 1022722) the design of the filter to purify water from solid and emulsified inclusions. The known filter contains a housing with inlet and outlet pipes and coarse-grained (crushed stone) and fine-grained (sand) filter media located in the housing, while the fine-grained filler is located in the coarse-grained pore space, the latter is not expanded during washing, and the ratio of the heights of the coarse-grained and fine-grained downloads is 1: 0.3-0.8.

A disadvantage of the known filter design is weak retention due to suboptimal loading composition of such water contaminants as compounds of ferrous iron, hydrogen sulfide, heavy metals, humates.

Known (SU, copyright certificate 1754174) granular filter containing filter elements, the housing of which is filled with granular material (gravel). The filter elements are arranged in a circle. In addition, the filter is equipped with a device installed on the axis of the circle for loading granular material.

A disadvantage of the known filter design is weak retention due to suboptimal loading composition of such water contaminants as compounds of ferrous iron, hydrogen sulfide, heavy metals, humates.

A known design (RU, patent 41303) of a filter for water purification, comprising a frame installed in a reservoir with a filler placed inside it for cleaning. The bottom of the reservoir carries a layer of gravel, the side walls of the reservoir carry a layer of gravel and concrete supports and bases with the formation of a rigid transverse opening to accommodate a frame having technological eyes and a galvanized wire mesh or perforated walls. As a filler, ion-exchanged natural or artificial crushed stone sorbents with fraction sizes made with the possibility of eliminating the overflow of waste water through the upper surface of the frame were used. In particular, it is recommended to use shungite, zeolite, and flask as sorbents.

A disadvantage of the known filter design is weak retention due to suboptimal loading composition of such water contaminants as compounds of ferrous iron, hydrogen sulfide, heavy metals, humates.

Known design (RU, patent 36938) installation of water purification. The installation comprises a chamber body with water inlet and outlet nozzles, a bulk filter with filter regeneration means and a pollution discharge means. The bulk filter is made multilayer, with different grain sizes, placed on a support perforated plate fixed in the lower part of the cleaning chamber, the filter layer adjacent to the support plate is fine-grained, and the upper layers are made with successively increasing grain size in the direction from the lower to the upper layer . The filter regeneration means is made in the form of an air distribution pipe connected to a source of compressed air and placed in the space between the support perforated plate and the bottom of the chamber body, the water inlet and outlet pipes are equipped with electric valves, and the contaminant discharge device is made in the form of a pipe with an inlet section located at the level of the upper surface of the filter, and equipped with an electric valve. In the case of a two-layer filter, sand with a particle size of 0.5-3 mm was used as the lower layer of the filter, and granite crushed stone with a particle size of 5-20 mm was used as the upper layer of the filter. In the case of a three-layer filter, sand with a particle size of 0.5-3 mm was used as the lower layer of the filter, granite crushed stone with a particle size of 5-20 mm was used as the middle layer of the filter, and crushed granulated as the upper layer of the filter quartz with a particle size of 20-40 mm, while preferably the height of the filter layers in the direction from the lower layer to the upper layer is correlated as 3: 2: 1. Instead of granite, basalt gravel can be used.

A disadvantage of the known filter design is weak retention due to suboptimal loading composition of such water contaminants as compounds of ferrous iron, hydrogen sulfide, heavy metals, humates.

The technical problem, the solution of which the present technical solution is directed, is the development of an improved design of a device for treating drinking water.

The technical result achieved by the implementation of the developed design of a device for treating drinking water is to reduce the total turbidity of the water by removing from the suspended water, in addition to suspended particles, contaminants such as compounds of ferrous iron, hydrogen sulfide, heavy metals and humates.

To achieve the specified technical result, it is proposed to use the developed device for drinking water purification, comprising a housing with nozzles for supplying purified water and withdrawing purified water, a bulk multilayer filter with different grain sizes and with means for filter regeneration and a nozzle for flushing water. A water supply pipe is connected to the housing through an aerator, a flush water discharge pipe is installed in the upper part of the body, and pipes for purified water discharge, flush water supply and drainage are located in the lower part of the body. A three-layer granular charge is located in the casing, the top layer of which is shungite, the second layer is quartz sand or anthracite, and the third layer consists of crushed stone, and a layer of manganese dioxide is placed on the surface of the particles of the charge. In the third layer of the granular load, there is a drainage system connected to the indicated pipes of the outlet for treated water, supply of flushing water and discharge to the sewer, made in the form of a set of tubes with holes connected to the central drainage pipe, the outlet of which is connected to the pipes of the outlet for purified water, supply of flush water and draining into the sewer, while on the outer surface of the tubes with a gap put on covers from the material passing through the purified water. Preferably, the pipes for treating treated water, flushing water and draining into the sewer are located in the lower part of the housing on its side surface. In one embodiment of the developed device, the pipes for treating purified water, supplying flushing water and draining into the sewer are located on a common outlet from the housing. Mostly the third backfill layer consists of granite, marble or quartz gravel. Tubes of the drainage system can be made with slotted or round holes. In a preferred embodiment, the particle size of schungite is from 1 to 5 mm, the particle size of the backfill of the second layer is from 0.6 to 3 mm, and the particle size of the backfill of the lower layer is from 5 to 40 mm. Mostly the ratio of the heights of the layers is 1: (2-7) :( 2-7). Covers can be made of filter cloth polyester or polypropylene fiber or nylon screens. Typically, the pore size in the covers does not exceed 0.3 mm, and the gap between the surface of the tubes and the covers is from 0.5 to 2.0 mm.

In the developed device, the mineral shungite, which is a natural complex sorbent combining the properties of silicate adsorbents and activated carbon, additionally activated by a layer of manganese dioxide deposited on it, was used as the first filtering layer. Manganese dioxide on loading grains (especially shungite grains) is a catalyst for the oxidation of dibasic iron to tribasic, the conversion of heavy metals to higher forms of oxidation, the oxidation of sulfur in hydrogen sulfide, and the oxidation of organic compounds. When purified water flows through a granular charge, especially coated with a layer of manganese dioxide and iron compounds, mechanical impurities are removed from it, both due to physical sorption on the grain surface and due to the catalytic effect of the bulk filter, which in fact is also a granular load. In addition, due to chemical interaction with manganese dioxide, the surface of shungite (and, possibly, anthracite), soluble impurities of elements of the iron group, heavy metals, hydrogen sulfide, humates, and other inorganic and organic compounds that determine the turbidity of water are removed from the water being purified. This filter load contributes to a significant reduction in the number of harmful microorganisms.

A drawback of drainage systems of known water purification devices (see, in particular, Nikoladze GI Water Supply. M., Stroyizdat, 1989) should be recognized as clogging with a granular loading of holes in drainage tubes. The indicated holes cannot be large enough so that the granular load does not get stuck in them, since in this case the grain of the load will enter the purified water, which will necessitate the installation of an additional filter. The indicated holes cannot be too small so that the loading grains do not block the holes, since this will significantly reduce the filter performance. To ensure the possibility of using a hole size optimal in performance in a water treatment plant, it was proposed to preferably use slotted holes in the drainage pipes and, in addition, to maximize the collection of purified water (and better distribution of washing water over the housing area), perform a drainage system in the form of a central drainage pipe , the outlet of which is connected to the pipes for the removal of purified water, the supply of flushing water and drain to the sewer, and to which the outputs of the small pipes of the drainage system are connected threads disposed at an angle (preferably straight) to said drainage pipe, with holes for the water flow through the drainage system is preferably made only in the drain tube, however, not excluded embodiment of the drainage system when in a central drain pipe formed as holes. The density of the drainage tubes in the drainage system depends on the estimated flow rate of the treated water.

For additional protection of the holes in the drainage system from clogging by the grains of the load, it is proposed to put covers made of permeable material with a gap on the indicated drainage tubes. Since the pore size in the covers is obviously smaller than the size of the loading grains, clogging of holes is practically excluded.

An ejector of a water-air system is preferably used as an aerator, although it is possible to use aerators of any design known at the time of designing the installation.

Figure 1 shows a view of a device made in a preferred embodiment (in section). Figure 2 shows the drainage system, with the following notation: case 1, pipe 2 for supplying purified water, aerator 3, first pipe 4 drain into the sewer, layer 5 schungite, layer 6 of quartz sand or anthracite, layer 7 of crushed stone, total output 8 pipes for the removal of purified water, supply of flushing water and drain to the sewer, a central pipe 9 of the drainage system, side pipes 10 of the drainage system, covers 11 of the drainage system.

The developed device operates as follows.

Pre-washed with water placed in the housing 1 of the device granular load 5-7 in order to remove polluting the granular load of 5-7 particles. The washing water is removed into the sewer through the pipe 4. Then, through the pipe 2, a solution of reagents capable of planting manganese dioxide (preferably a mixture of potassium permanganate and alkaline solutions of potassium permanganate) and iron hydroxide is fed to the grain loading 5-7 through a grain charge 5-7. These reagents after passing through a granular charge 5-7 with the formation of a layer of manganese dioxide are also removed into the sewer through pipe 8. Re-wash the granular charge 5-7 with water to remove traces of the reagent solutions.

To obtain clean drinking water, an aerator 3 is connected (the ratio of air and water consumption is preselected experimentally to control the turbidity of the purified water) and oxygenated water is fed through the pipe 2 to a granular charge 5-7. On shungite grains 5 coated with a layer of manganese dioxide, in the presence of oxygen, chemical elements (iron group, heavy metals, sulfur, organic compounds) are oxidized to higher oxidation states, which significantly improves water quality. Further oxidation occurs at layers 6 and 7. The purified water through the drainage system 9-11, and then through the pipe 8 enters the consumer.

Periodically, the aerator 3 is turned off, the flow of purified water is shut off, and the washing water is successively supplied through the nozzle 8, the drainage system 9-11 to the granular load 5-7. Then through the pipe 4 remove the wash water into the sewer.

When passing through the installation of the developed design of the source water containing 4.1 mg / dm ^{3 of} iron, 0.56 mg / dm ^{3 of} manganese and with a turbidity of 10 mg / dm ³ , the output is drinking water of qualification with an iron content of not more than 0.15 mg / l, manganese - 0.1 mg / l and a turbidity of not more than 1.4 mg / dm ³ .

Claims (12)

1. A device for treating drinking water, comprising a housing with nozzles for supplying purified water and drainage of purified water, a bulk multilayer filter with different grain sizes and with means for regenerating the filter, a nozzle for draining the wash water, characterized in that the nozzle for supplying water is connected to the housing through an aerator , in the upper part of the body there is a pipe for draining the wash water, in the lower part of the body there are pipes for draining the purified water, for supplying the washing water and draining into the sewer, a three-layer a granular load, the top layer of which is shungite, the second layer is quartz sand or anthracite, and the third layer consists of crushed stone, with a layer of manganese dioxide placed on the surface of the particles of the load, in the third layer of the granular load there is a drainage system made in the form of a set of tubes with openings connected to the central drainage pipe, the outlet of which is connected to the pipes for the removal of purified water, inlet of flushing water and drain into the sewer, while covers are placed on the outer surface of the tubes with a gap from the material passing the purified water. 2. The device according to claim 1, characterized in that the pipes for draining purified water, supplying washing water and draining into the sewer are located in the lower part of the housing on its side surface. 3. The device according to claim 1, characterized in that the pipes for draining purified water, supplying flushing water and draining into the sewer are placed on a common outlet from the housing. 4. The device according to claim 1, characterized in that the third loading layer consists of granite, marble or quartz gravel. 5. The device according to claim 1, characterized in that the tubes of the drainage system are made with slotted or round holes. 6. The device according to claim 1, characterized in that the particle size of shungite is from 1 to 5 mm. 7. The device according to claim 1, characterized in that the particle size of the load of the second layer is from 0.6 to 3 mm 8. The device according to claim 1, characterized in that the particle size of the load of the third layer is from 5 to 40 mm 9. The device according to claim 1, characterized in that the ratio of the heights of the upper, second and third layers is 1: (2-7) :( 2-7), respectively. 10. The device according to claim 1, characterized in that the covers are made of filter cloth made of polyester or polypropylene fiber or nylon screens. 11. The device according to claim 10, characterized in that the pore size in the covers does not exceed 0.3 mm 12. The device according to claim 1, characterized in that the gap between the surface of the tubes and the covers is from 0.5 to 2.0 mm

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