RU183672U1 - DEVICE FOR FINE CLEANING OF WATER WITH A FILTERING ELEMENT BASED ON POROUS TITANIUM - Google Patents

Abstract

The utility model relates to devices for the fine purification (microtreating) of household water, as well as industrial effluents from mechanical impurities, free chlorine, nitrates, carbon tetrachloride, oil products, colored organic substances that worsen the color index of water, iron, aluminum, manganese ions, as well as pathogenic bacteria. SUBSTANCE: device for fine water purification comprises a housing, a cover with nozzles for supplying a cleaned liquid and drainage of the filtrate, a filtering element centered in the housing, made of whole porous titanium with a labyrinth pore structure with a size from 0.1 μm to 4.9 μm and porosity of 80- 95%, and the inner cavity of which communicates with the outlet of the filtrate, the filtration chamber formed by the housing and the outer surface of the filter element, in communication with the nozzle for supplying the cleaned liquid. The technical result of the utility model is to increase its functionality, reliability, manufacturability of the design of the device for fine water purification and, accordingly, to increase the life of the device due to the simplification of its design, the assembly-disassembly process, which is achieved by the ease of installation of the filter element, by reducing the filter layers of the filter element design without reducing the effectiveness of water treatment, fixing and centering in the body of a single filter element made of porous Titan with optimal structural characteristics: pore size, porosity, that, in general, provides ease of operation while maintaining a high degree of water purification.

Description

The utility model relates to devices for the fine purification (micro-purification) of household water, as well as industrial effluents from mechanical impurities, free chlorine, nitrates, carbon tetrachloride, oil products, colored organic substances that worsen the color index of water, iron, aluminum, manganese ions, as well as pathogenic bacteria.

A known design of a filter for water purification, including a housing, a cover with channels for supplying the liquid to be cleaned and drainage of the filtrate, a filter element with a cylindrical side surface, the inner cavity of which communicates with the filtrate removal channel, a filtration chamber formed by the housing and the outer surface of the filter element in communication with the supply channel the liquid being cleaned [RU 17010, 03/10/2001]. In this case, the filter element is made of a porous material based on titanium carbide.

The disadvantages of this filter can be attributed to insufficient insufficiently high degree of water purification during removal: hardness salts (magnesium, calcium, silicon) and fluorine, as well as a narrow range of pollutants available for cleaning, due to the fact that titanium carbide was chosen as the material of the filter element , which, as you know, does not enter into chemical reactions with hardness salts and fluorine.

For the closest analogue to the claimed utility model adopted the design of the installation for micro-purification of liquids, which contains a detachable housing with an inlet pipe for supplying the source liquid and an outlet pipe for the outlet of the purified liquid [RU 2288172, 11/27/2006]. A cartridge is placed in the casing, which is an outer cylinder located concentrically to each other and the casing, from a single-layer woven stainless steel mesh stretched over a frame made of a perforated stainless steel sheet in the form of a cup, an average cylinder made of porous polypropylene with a filter fineness of 20 microns on the outer surface, up to 5 microns on the inner surface, on the lower end of which a sealed elastic plastisol patch is welded along the cylinder diameter, and on the upper end is plastisol ring welded on een outdoor diameter 1 mm larger than the inner diameter of the annular rim and outer cylinder with an inner diameter 1 mm smaller than the diameter of the inner cylinder, the inner cylinder made of sintered titanium powder with a predominant pore size of 5-7 microns.

The disadvantage of the installation for micro-purification of liquids lies in the complexity of its design, including a filter cartridge, consisting of three filter layers, as well as an auxiliary element fixing the filter layers. In addition, the design of the device implements a rather laborious cartridge fastening scheme, since for mounting the filter cartridge it is necessary to insert the liquid outlet pipe located on the removable cover of the device into a small hole in the upper part of the cartridge, while the lower part of the cartridge must be installed evenly in the lower part housing on the side surface of a conical shape without fixing. The absence of cartridge fixing elements in the design of the device can lead to a constant displacement of the cartridge under the pressure of water and helps to accelerate the wear of parts during operation, as well as uneven contamination of the filter cartridge, thus requiring more frequent cartridge regeneration, otherwise, the degree of water purification may decrease significantly. Thus, these disadvantages lead to a decrease in the reliability of the device during operation and the effectiveness of water treatment.

Another disadvantage of the device is that the porous titanium layer of the filter cartridge is not sufficiently high in liquid purification due to the non-optimal structural characteristics of this material with a pore size of 5-7 microns, which requires the use of two additional filter layers, as a result of which a three-stage is implemented to obtain a high degree of water purification cleaning scheme.

The technical problem to be solved by the claimed utility model is to expand the arsenal of means of non-reagent fine water purification with a simple design that allows you to remove a wide range of contaminants with high efficiency in a single-stage scheme.

The technical result of the utility model is to increase its functionality, reliability, manufacturability of the design of the device for fine water purification and, accordingly, increase the life of the device by simplifying its design, the assembly-disassembling process, which is achieved by the ease of installation of the filter element, by reducing the filter layers of the filter structure element without reducing the efficiency of water purification, fixing and centering in the casing of the whole filter element of porous titanium with optimal structural characteristics: pore size, porosity, which, in general, provides ease of use while maintaining a high degree of water purification.

The specified technical result is achieved in a device for fine water purification, comprising a housing, a cover with nozzles for supplying the liquid to be cleaned and for removing the filtrate, a filter element centered in the housing, made of whole porous titanium with a labyrinth pore structure with a size from 0.1 μm to 4.9 microns and porosity - 80-95% and the internal cavity of which communicates with the outlet of the filtrate, the filtration chamber formed by the housing and the outer surface of the filter element in communication with the nozzle for supplying the cleaned liquid tee.

The body of the device for deep water purification can be made of stainless steel or a polymeric material and is designed to install cylindrical filter elements with a length of 8 cm to 1000 cm with a wall thickness of 0.1 to 10 cm.

In the upper part of the filter element there is a pipe with an external thread for firm fastening and centering in the lid of the device. Accordingly, a mating internal thread is made on the water pipe or adapter.

The filter element has an internal cavity in communication with the device filtrate outlet pipe and centered relative to the filtrate receiving port of the filtrate outlet pipe.

The choice of titanium as the only material for the manufacture of the filter element in the form of a cartridge and the implementation of the filter element with a highly porous labyrinth structure with an open pore size of 0.1-4.9 μm, most preferably 0.1 μm, and porosity of 80-95%, most preferably 95%, it is possible to achieve high rates of water purification from the previously mentioned pollutants, which is due to the well-known beneficial properties of titanium in water purification, for example, the catalytic properties of metal oxidation, for example, iron, b bactericidal properties, etc., and the optimal structural characteristics of the porous filter element. A decrease in pore size and, at the same time, an increase in the porosity of the material leads to an increase in the adsorption surface area of the filter element. In addition, the finely porous labyrinth structure of the filter element allows to retain particles of substances removed from the water due to mechanical inhibition at the site of the pore gyrus.

Thus, the implementation in the design of the device of a filter element made of porous titanium with optimal structural characteristics can improve the efficiency of water purification from a wide range of contaminants while simplifying the design of the device, namely, by reducing the number of additional filter layers of the filter element to one, which also increases the reliability of the device in general, and increases the service life.

The compactness of the filter element is due to the presence of one filter layer, as well as the implementation of a simple fastening connection in the upper part of the filter element, for example, in the form of a thread, for fastening and centering in the device body, which accordingly simplifies its installation and assembly of the device as a whole, while achieving high fixation strength of the filter element in the housing, which eliminates undesirable movement of the filter element, leading, on the one hand, to the wear of the device parts, and other - to uneven contamination of the filter and reducing the effectiveness of water purification. Thus, the design of the utility model is characterized by high reliability and a consistently high degree of water purification.

The essence of the utility model is illustrated by a figure, which shows a frontal section of a device for fine water purification.

In the figure, positions 1-12 indicate:

1 - housing;

2 - cover;

3 - inlet pipe;

4 - outlet pipe;

5 - a collar;

6 - a sealing ring;

7 - filter element;

8 - sleeve with external thread;

9 - drain fitting;

10 - a stub;

11 - filter chamber;

12 - cavity in the filter element.

The design of the device for fine water purification includes a housing 1, a cover 2 with nozzles for the inlet 3 and outlet 4 of the liquid, a clamp 5 with a rubber seal for attaching the housing to the cover, a sealing ring 6 of the clamp, a filter element 7 made of porous titanium, with a sleeve located in the upper part 8 with an external thread for screwing into the housing 1. At the bottom of the housing there is a drain fitting 9 with a plug 10.

In the particular case of implementation, the filter housing and the cover are made of stainless steel with the height of the device being 37 cm and the inner diameter of the housing 9 cm. The height and outer diameter of the filter element are 22.8 and 5.6 cm, respectively. In this case, the wall thickness of the filter element is 3 cm. To install the titanium filter element 7, it is necessary to remove the clamp 5 and disconnect the housing 1 from the cover 2, and then screw in the filter element with a thread along the axis of the cover. The filter element is screwed into the housing so that the opening of the inlet pipe for the entrance of the water to be cleaned in the housing is located directly above the wall of the filter element. This contributes to the primary treatment of water with vertical passage of water through the wall and secondary treatment when passing through the filter element in a horizontal direction. The filter element is made of porous titanium with a labyrinth pore structure with a size of 0.1 μm and a porosity of 8 cm. Next, the cover is put on the housing and secured with a clamp. The filter housing can be mounted using a bracket mounted on a vertical surface.

The given example is a special case and does not exhaust all possible implementations of the utility model.

Water treatment is carried out as follows: through the inlet pipe in the cover 2, water enters the device body and undergoes primary cleaning, passing vertically through the wall of the filter element, after which the water enters the filter chamber 11 and passes through the filter in the horizontal direction into the cavity of the filter element 12. Moreover, all substances and bacteria to be removed are retained on the walls of the filter element, directly due to adsorption in the pores of porous titanium, inside the pores due to fur nical braking place gyrus pores and also on the pore surfaces without penetrating inside. Then, purified water from the cavity in the filter element 12 enters the outlet pipe 4. The pollutants retained by the filter element, including water-insoluble iron oxide, formed as a result of catalytic oxidation of iron ions on the surface of porous titanium coated with a titanium oxide film, which is a catalyst for the process oxidation of metals during regeneration of the filter by the reverse flow of water is easily washed off the surface of the filter element.

Tables 1, 2 show the results of determining the effectiveness of water purification with different concentrations of pollutants using this utility model.

¹⁾ A water sample was purified by a device with a filter element made in its housing with a pore size of 0.1 μm and a porosity of 95%;

²⁾ A water sample was purified by a device with a filter element made in its housing with a pore size of 0.8 μm and a porosity of 95%;

³⁾ A water sample was purified by a device with a filter element made in its housing with a pore size of 4.9 μm and a porosity of 95%;

⁴⁾ In parentheses indicate the degree of water purification in% relative to the wastewater sample before cleaning with a filter.

¹⁾ A water sample was purified by a device with a filter element made in its housing with a pore size of 0.1 μm and a porosity of 95%;

²⁾ A water sample was purified by a device with a filter element made in its housing with a pore size of 0.1 μm and a porosity of 90%;

³⁾ A water sample was purified by a device with a filter element made in its housing with a pore size of 0.1 μm and a porosity of 80%;

⁴⁾ In parentheses indicate the degree of water purification in% relative to the wastewater sample before cleaning with a filter.

The best results of water purification from a wide range of contaminants were obtained using a utility model with a pore size of 0.1 μm and a porosity of 95% of the filter element.

As a result of determining the content of some pollutants in water samples before and after purification using this utility model, it was found that the samples of purified water in terms of the concentration of pollutants contained in them comply with SanPiN 2.1.4.1074-01 for drinking water and household water.

Thus, the developed design of the device for thin water with a filter element based on porous titanium is characterized by high reliability and efficiency of water purification from a wide range of pollutants, which is achieved by simplifying its design, using porous titanium with optimal structural characteristics and its strong fixation as a filter element in the case.

Claims (5)

1. A device for fine purification of water, comprising a housing, a cover with nozzles for supplying the liquid to be cleaned and drainage of the filtrate, characterized in that the filter element is centered in the housing and is made of whole porous titanium with a labyrinth pore structure with a size from 0.1 μm to 4, 9 microns and porosity of 80-95%. 2. A device for fine water purification according to claim 1, characterized in that the filter element is centered in the housing by means of a connecting element fixing the filter element in the housing. 3. A device for fine water purification according to claim 2, characterized in that the connecting element is a sleeve with an external thread. 4. A device for fine water purification according to claim 1, characterized in that the filter element has an internal cavity in communication with the filtrate outlet pipe and centered relative to the filtrate receiving hole of the filtrate outlet pipe. 5. A device for fine water purification according to claim 1, characterized in that the housing and the outer surface of the filter element form a filtration chamber in communication with the nozzle for supplying the liquid to be cleaned.

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