RU2243021C1 - "mions" filter for purification of potable water - Google Patents

Abstract

FIELD: sanitary engineering; purification of potable water.

SUBSTANCE: the invention is intended for purification of potable water and is dealt with the field of sanitation equipment, in particular, with filters for purification of potable water and may can be used in other fields of engineering. The body is made in the form of two conjugated parts, the upper part of which has form of a cylinder, the lower part - the form of a truncated cone with a taper bottom and an axial hole. On the surface of the conical part of the body there is a protrusion, under which a gasket is located. On the surface of the conical part of the body there are vertical stiffening ribs. Along the axis of the body a separating cylinder with holes is installed. Inside the cylinder on its taper bottom a flat-bottomed filter element is installed, thickness of the bottom of which exceeds thickness of the wall, and the internal surface of the bottom is located at the level of the side holes of the separating cylinder. Between the external surface of the bottom and the internal surface of the separating cylinder there is a space sealed by a centering ring. The filter body is filled in with a granular material of different natural minerals, which form stages of purification and are located along the axis of the body and conjugated among each other through a separating gasket. On an external surface of a mineral there is a separating gasket, on which a lattice is installed. The volume of a material of the first stage exceeds the volume of the consequent stages. A rigid fixing of the elements located inside the body is made with the help of a nut having a hole. In the lower part of the nut there is a deepening, in which the gasket with a hole is placed. The separating cylinder side holes are shut with a porous material and the external surface of the filtering element is protected with the help of the porous material. The technical result is improvement of quality of water purification, increased service life of the filtering element and the filter and also decreased cost of the purified water and expansion of operation of the filter.

EFFECT: the invention ensures improvement of quality of water purification, increased service life of the filtering element and the filter, decreased cost of the purified water.

5 cl, 3 dwg

Description

The invention relates to the field of sanitary engineering, in particular to filters for treating drinking water, and can be used in other fields of technology.

A known filter for treating drinking water, comprising a housing, a filter element in the form of a cylinder with a bottom and a centering ring, a nut with a gasket [1].

A disadvantage of the known filter is the lack of a preliminary stage of cleaning from coarse, mechanically saturated impurities: clay, sand, pipe rust, chemical compounds to be pre-cleaned, however, the filter design does not implement a three-stage cleaning of impurities, but only one-stage cleaning.

A known filter for the purification of drinking water, comprising a housing filled with granular material from various natural minerals and separated by a grill, a housing cover with holes for water inlet and outlet [2].

The disadvantage of the filter is the lack of a separating pad between the steps, as well as the absence of a preliminary cleaning step from a coarse impurity mechanically saturated in water.

The closest technical solution, selected as a prototype, is a filter for drinking water purification, containing a housing, a cover, a filter element, which is made of porous synthetic material in the form of a cylinder with a bottom and filled with a fine-grained sorbent [3].

A disadvantage of the known filter is the lack of rigid fixation of the sorbent with a low tensile strength. Under the influence of the flow of water entering through the filter element shell, the sorbent grains - coal - move and experience friction. As a result of friction, impurity particles adsorbed on the grain surface are simultaneously removed from the surface of the coal grains, which return to the water. Thus, the water is re-contaminated with a double admixture of adsorbed impurity particles and coal particles, which contaminates the inner surface of the shell, thereby reducing the permeability of the shell material, reducing productivity and reducing the filter life, which affects the quality of water purification from impurities.

A significant drawback of the filter is the limited ability to design a system for cleaning impurities dissolved in water, various metal oxides and chemical elements that cause water hardness, radioactive elements and other harmful impurities in water. The limited capabilities of the filter respectively limits the possibility of using the filter in other areas of technology.

The technical result of the invention is to improve the quality of water purification due to two-system and simultaneously sequential purification, increasing the life of the filter material due to the stage of preliminary cleaning of coarse, mechanically saturated impurities, expanding the functionality of the filter.

This result is achieved in that the filter for drinking water purification has two impurity purification systems, the first system is based on natural materials, and the second is based on synthetic material, which simultaneously and sequentially perform the function of purifying impurities, the filter housing is made in the form of two conjugated parts of the cylinder and a truncated cone with a conical bottom and an axial hole in the bottom, at the top of the cylindrical part there is an annular protrusion, under which a gasket is placed, and on top of the protrusion there is a lid housing, on the outer surface of the conical part of the housing there are vertical stiffeners that act as balancing elements when installing the filter in the filler opening of the storage tank and air outlet when filling it with water. The conical shape of the filter allows you to use any container whose filling hole corresponds to the outer diameter of the filter housing. The presence of two impurity purification systems can improve the quality of purified water.

The cavity of the casing is filled with filtering natural mineral, which forms the steps of the first cleaning system, each step performs the function of cleaning from a certain impurity, the steps are located along the axis of the casing and are interconnected through a spacer gasket, on the outer surface of the mineral of the first step of the first system there is a spacer gasket on which a lattice is installed, the volume of the mineral of the first stage exceeds the volume of the mineral of the subsequent stages. The first step of the first system delays coarse, mechanically saturated impurities - clay, sand, rust pipes and other chemical fractions, insoluble in water. The mechanical impurity quickly contaminates the surface and the volume of the filter material of all subsequent cleaning stages. Therefore, the first stage of the first cleaning system is determining the quality of cleaning and increases the resource of the material, and in general, the duration of the filter, and therefore the quality of water treatment. The second stage adsorbs gases (chlorine, hydrogen sulfide) eliminates odor, improves the organoleptic, antimicrobial and environmental properties of purified water.

The third stage of the first system is filled with filter material - zeolite. The stage performs the function of delaying the impurities of various metals and ferrous compounds. The mineral zeolite used has a wide range of physicochemical properties and a different mechanism for the adsorption of an impurity, depending on the nature of the impurity.

A separating cylinder with side openings that are covered by a porous material is installed inside the conical part of the housing. The presence of a separation cylinder allows for a two-system and at the same time sequential cleaning of impurities. A filter element of the second system, made of synthetic material in the form of a hollow cylinder with a flat bottom, is installed on the conical bottom of the housing; a high molecular weight material is placed on the outer surface of the element. The bottom thickness H exceeds the wall thickness h of the cylinder. The inner surface of the bottom is installed at the level of the side holes of the separation cylinder. The space between the outer surface of the bottom and the inner surface of the separation cylinder is sealed with a centering ring, which made it possible to use the full volume of the bottom material as a stage of the second cleaning system. The presence of a two-system cleaning and the design of the filter element of the second system in the form of a hollow cylinder with a bottom make it possible to use, as a three-stage cleaning, the geometric elements of the cylinder, its external surface as the first stage of cleaning; the wall thickness h as the second stage of cleaning and the thickness of the bottom H as the third stage.

Rigid fixation of the filter elements and sorbing minerals in the steps located inside the housing is carried out by a compression nut with a hole, a recess is made in the lower part of the nut, in which a gasket with a hole for air to exit the cavity of the filter element is placed.

Thus, the claimed filter for drinking water purification meets the criterion of "novelty."

Comparison of the proposed solution for purification from drinking water impurities with the prototype under consideration and with other technical solutions did not allow us to identify signs that distinguish the claimed solution from the prototype, which allows us to conclude that the criterion is “significant differences”.

The invention is illustrated in the drawing, where Fig.1 schematically shows a General view of the filter in section; figure 2 shows the lattice in cross section aa; on figa shows a General view of the lattice.

The filter has two systems for purifying water from impurities, one of which is based on natural materials, and the second based on synthetic material, both systems simultaneously and sequentially purifying water from impurities, the filter housing is made in the form of two mating parts of cylinder 1 and a truncated a cone 2 with a conical bottom 3 and an axial hole 4 in the bottom, an annular protrusion 5 is made at the top of the cylindrical part of the housing, under which a gasket 7 is placed, and a cover 6 is placed on the outer surface of the protrusion, on the outer surface In the conical part of the casing there are vertical stiffening ribs 8, which act as balancing elements when a storage tank is installed in the opening and provide a gap for air to escape from it when filling with water, a separating cylinder 9 with side openings 10 that are closed with a porous material is installed inside the conical part of the casing 11, the body cavity is filled with fine-grained material from various natural minerals that form steps 12, 13 and 14 of the first cleaning system, steps are located along si of the housing and are interfaced through the separation gasket 15, on the outer surface of the mineral of the first stage on the separation gasket 15 there is a grill 16, the volume of the mineral of the first stage 12 exceeds the volume of the mineral of the next steps, a filter element 17 is installed on the conical bottom 3 of the housing, forming a second cleaning system, made in the form of a hollow cylinder with a bottom 18, porous macromolecular material 19 is placed on the outer surface, the bottom thickness H exceeds the wall thickness h of the cylinder, the inner bottom surface 20 is installed and at the level of the side holes 10 of the separation cylinder 9, the space between the outer surface of the bottom and the inner surface of the separation cylinder 9 is sealed with a centering ring 21, the filter elements and the sorbing minerals of the steps are rigidly fixed by the compression nut 22 with the hole 23, a recess is made in the bottom of the nut, in which placed the gasket 24 with a hole 25 for the exit of air from the cavity of the filter element.

The filter works as follows.

Pre-install the filter down the conical part of the housing into the filler hole of the storage tank, pour the required amount of water from the water supply on top of the grill 16. Water through the holes of the lattice 16, the gasket 15 enters the first stage 12 of the first system, in which preliminary cleaning of mechanically saturated impurities is carried out. If the mineral is heavily contaminated, it must be removed from the housing, rinsed in running water and installed for reuse. After preliminary cleaning in the first stage of the first cleaning system, water flows through the spacer 15 into the second stage 13 and then flows sequentially through the spacer 15, stage 14, porous material 11, through the side holes 10 and fills the cavity of the spacer cylinder 9, according to the principle of a communicating vessel, over the entire height of the cylinder, air from the cavity of the filter element 17 is removed through openings 23 and 25, water passes through the wall thickness h, then through the bottom H and through the opening 4 enters the storage tank (for hours The drawing does not indicate) purified water. When reducing the flow of water from the opening 4, the filter element 17 should be removed from the cavity of the separation cylinder 9, regenerate it in accordance with the instructions, and then set for reuse. When using the filter in flowing mode, the filter is installed in the line, sealed with gasket 7 and connected to the water supply, and discharged through the outlet of the line (not shown in the drawing).

The filter can be implemented as follows.

The housing, nut, grille, and separation cylinder are made of low-pressure polyethylene or stainless material, since these materials are not subject to corrosion and have high mechanical strength. O-rings, gaskets are made of food rubber. Separation gaskets between the steps of the first cleaning system and the side openings of the separation cylinder of the second system are made of porous material, natural minerals are used as the material of the steps of the first cleaning system: the first step is pyrolyusite mineral; the second step is shungite and the third step is the zeolite mineral. As a three-stage cleaning of the second system, a filter element in the form of a cylinder made of a material with ion-exchange properties was used, a porous high molecular weight material was placed on the outer surface of the cylinder, which performs the function of a preliminary cleaning stage of the second system, and a filter element in the form of a cylinder allows the use of cylinder geometric elements as stages of cleaning . Use the external surface as the first stage, the wall thickness h as the second stage, and the bottom thickness H as the third stage.

The placement of high molecular weight material on the outer surface of the filter element made it possible to adsorb in the bulk of the material the remainder of the impurity of low concentration after the first cleaning system.

Due to the presence of free radicals in the material as a result of water filtration through the material in the volume, a loose structure of an adsorbed impurity forms, which does not affect the permeability of water through the surface of the wall thickness h of the cylinder into its cavity, which made it possible to realize the second stage of cleaning, and as a third stage use the bottom of N.

Rigid fixation of the mineral in the steps completely eliminates friction and the formation of friction particles, and the presence of a separation pad between the steps eliminates the transition of residual impurities to the next step. In the second stage, the natural mineral shungite was used, which has high mechanical strength, and a high carbon content of up to 96%, in terms of sorption properties corresponds to activated carbon, in addition, it has additional properties to disinfect pathogens, as well as high activity in the absorption of gases dissolved in water, chlorine-containing and organophosphorus compounds, including petroleum products. The use of shungite improves the toxicological, organoleptic and environmental characteristics of purified water, which determined the choice of shungite as the second stage of treatment. As the third stage of the first purification system, we used the natural mineral zeolite, which exhibits a different adsorption mechanism to a different type of impurity, which made it possible to carry out high-quality water purification and reduce its hardness.

Separation of filtering minerals into steps provides sequential purification of a certain impurity in the steps. After purification of the impurity in the first stage of the first system, the concentration, size and composition of the impurity is reduced and thereby the adsorption load on all subsequent stages and stages of the purification system is reduced, which made it possible to improve the quality of purified water and increase the service life of the filter.

The mechanical strength and hardness of the minerals used as purification steps, as well as the ease of regeneration of filter materials, made it possible to reuse the filter material, increase its life in comparison with the prototype and other known filters, and a double impurity purification system made it possible to obtain high-quality purified water. The design of the casing made it possible to expand the operational capability and use a filter with any storage capacity.

SOURCES OF INFORMATION

1. Operation manual “Filter generated by household“ Geyser ”. LLC "Water Area", M., 2002.

2. Passport and instruction manual “Household filter for water purification based on minerals“ Desktop ”. M., 2001.

3. Copyright certificate of the USSR, No. 874121, cl. B 01D 24/10, 1981 (prototype).

Claims (5)

1. The filter for drinking water purification, comprising a housing, a cover, a filter element with a bottom with a hole and filled with different types of filter material, characterized in that the filter has two impurity water purification systems that are made: one based on natural minerals, and the second based on synthetic material, both systems simultaneously simultaneously cleaning from impurities, the filter housing is made in the form of mating parts of the cylinder and a truncated cone with a conical bottom and an axial hole in the bottom, at the top of the cylinder of the casing part, an annular protrusion is made under which the gasket is placed, and the casing cover is placed on top of the protrusion, on the outer surface of the conical part there are vertical stiffeners that act as balancing elements when installed in the opening of the storage tank and provide a gap for air to exit from it when filling water, inside the conical part of the housing there is a separation cylinder with side holes at the bottom of the cylinder, which are closed with porous material, the cavity of the housing is filled with a filter the forming material from various natural minerals that form the steps of the first impurity removal system, the steps are located along the axis of the casing and are interfaced through a spacer gasket, a grill is installed on the outer surface of the mineral of the first step on the spacer gasket, the volume of the mineral of the first step exceeds the volume of the mineral of the next steps, the conical bottom of the housing has a filter element forming a second cleaning system made of synthetic material in the form of a hollow cylinder with a bottom, and and its outer surface contains porous macromolecular material, the bottom thickness H exceeds the wall thickness h of the cylinder, the inner bottom surface is installed at the level of the side openings of the separation cylinder, the space between the outer surface of the bottom and the inner surface of the separation cylinder is sealed with a centering ring, the filter elements placed inside are rigidly fixed case, and sorbing minerals in the steps is carried out with a clamping nut with a hole, in the bottom of the nut is made deepened e, wherein the gasket is placed with a hole for air to escape from the cavity of the filter element. 2. The filter according to claim 1, characterized in that the mineral pyrolyusite is used as the first stage of the first cleaning system. 3. The filter according to claim 1, characterized in that the mineral shungite is used as the second stage of the first cleaning system. 4. The filter according to claim 1, characterized in that the mineral zeolite is used as the third stage of the first purification system. 5. The filter according to claim 1, characterized in that as a second cleaning system a filter element is used in the form of a cylinder of ion-exchange material, on the external surface of which a porous material is placed, which performs the function of a preliminary stage of purification from impurities, and the external surface of the filter element is used the wall thickness h was used as the first stage of cleaning, the wall thickness h was used as the second stage, and the bottom thickness H of the filter element was used.

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