RU68348U1 - FILTER MATERIAL AND BACTERICIDAL DEVICE - Google Patents

Abstract

The utility model relates to devices that provide fine purification of liquids from suspensions, dissolved chemical compounds and bacteria. The filter material contains a porous base and a material with bactericidal properties, while a filter film made of a track membrane is used as a porous base, and the bactericidal material is made in the form of an additional layer placed on the filtering surfaces of the film. The film thickness is from 7 to 25 microns, the diameter of the through pores is from 0.05 to 0.4 microns, the thickness of the bactericidal material is not more than 1 mm. As a bactericidal material, a material is used containing either silver and / or its compounds, or iodine and / or its compounds, or chlorine and / or its compounds, or fluorine and / or its compounds, or benzalkonium chloride. It is possible to use a bactericidal sorbent. The bactericidal device comprises a housing provided with at least one fitting and a filter element made of the filter material described above. The pressure-free filtering device preferably comprises a flat housing provided with an outlet fitting and a filter element located outside the housing on its bearing surfaces with which the filter element is hermetically connected around the perimeter. A device for cleaning liquids, directed under pressure, contains a detachable housing and a filter element made in the form of a filter cartridge and attached tightly around the perimeter to the surface of the supporting frame. One of the parts of the housing is equipped with inlet and outlet fittings. The utility model can be used in systems for producing drinking water and purifying liquids. 2 n.p.ph., 16 c.p.f., 4 fig.

Description

The utility model is intended for cleaning liquids, both at home for individual consumers and for industrial purposes, and relates to devices that provide fine purification of water from suspensions, bacteria, and chemical compounds dissolved in water.

Known filter material for cleaning liquid and gaseous substances, made in the form of a porous base with a selective layer based on transition metal oxides (RF Patent No. 13949, IPC B01D 69/10. Material for cleaning liquid and gaseous substances. Published on June 20, 2000) . In a known utility model, the pore size of a porous base made of transition metal oxides is from 0.001 to 0.03 μm, the filter material is provided with an additional discrete layer located on the porous surface of the filter material. The discrete layer is made of radiation-generated silver nanostructured particles with the formation of ultrafiltration material with bactericidal properties. The disadvantages of the described technical solution include the instability of the composition of the porous base, the ability to clean small volumes of liquid and gaseous substances, as well as the need for a relatively high concentration of silver ions in the discrete layer of ~ 0.150 mg / l for effective exposure to bacteria. However, the maximum permissible concentration (MPC) of silver in water is 0.050 mg / l, since silver is a heavy metal, and its presence in amounts exceeding the MPC has a negative effect on the human body.

The closest technical solution to the claimed filter material is a filter material comprising a porous base made of a polymeric material with

the addition of carbon, and a discrete layer of nanostructured silver particles (RF Patent No. 54811, IPC B01D 39/08. Filter material for cleaning liquid and gaseous substances and a bactericidal device. Published July 27, 2006 Bul. No. 21). The disadvantages of the utility model include a significant pore size dispersion of the porous base and the presence of a high concentration of silver ions in the discrete layer.

Known household filter for fine water purification (RF Patent No. 2145943, IPC B01D 29/56. Household filter for fine water purification. Published on February 27, 2000). The known technical solution comprises a housing closed by covers, has a hose for draining filtered water, prefilters and filter elements located between the housing and covers, openings for water intake are made in the covers, the housing surface is grooved, the collector for collecting the filtrate is formed by this surface and the surface of the filter element is made of polymer polyethylene terephthalate film (track membrane). The described technical solution relates to devices that provide fine purification of water from suspensions, bacteria, viruses and chemical compounds dissolved in water. The disadvantages of the invention include the following. Indeed, bacteria are retained by the track membrane, and according to the invention, their retention efficiency is ~ 99%. However, such efficiency is achieved only at the initial stage of filtration (when filtering the first ~ 15 liters of water), in the future, the filtration efficiency decreases to ~ 55-94%. In addition, even if the track membrane retained absolutely all bacteria, when they get into comfortable conditions for reproduction (room temperature, 100% humidity, food availability), bacteria can significantly increase their number due to the fact that they are living organisms. And if we take into account that bacteria can modify their shape in order to “crawl” through narrow holes, then the guaranteed purification of water from bacteria with the help of only a track membrane with pore sizes from 0.2 to 0.4 μm does not

out of the question. This disadvantage of membrane filters is especially evident during periodic operation of the device, when in the absence of circulation even one or two colonies of "crawled" bacteria can multiply in such a quantity that during the next cycle of operation the devices fall into the "glass" and can harm human health.

The closest technical solution to the claimed bactericidal device is a device containing a housing with inlet and outlet fittings and a filter element made of a filter material comprising a porous base made of a polymer material with the addition of carbon and a discrete layer of silver nanostructured particles (RF Patent No. 54811 , IPC B01D 39/08 Filtering material for cleaning liquid and gaseous substances and a bactericidal device Published July 27, 2006 Bull. No. 21). The disadvantages of the known bactericidal device are due to the disadvantages of the used bactericidal material described above.

The authors of the proposed technical solution had the task to eliminate these shortcomings and to develop a filter material with high bactericidal properties and effective bacteriostatic action, as well as a bactericidal device that allows filtering liquids with high cleaning efficiency not only from dissolved chemical compounds and suspensions, but also from bacteria .

To solve this problem, a filter material and a bactericidal device are proposed. The inventive filter material contains a porous base and a material with bactericidal properties and is characterized in that a filter film made of a polymeric material, such as a track membrane or similar material, is used as a porous base, and a material with bactericidal properties (hereinafter referred to as bactericidal material) is made in the form of an additional layer, placed at least on one of

filtering surfaces of the film. The thickness of the filter film is preferably 7-25 microns, and the diameter of the through pores is from 0.05 to 0.4 microns. It is advisable to perform a layer of bactericidal material with a thickness of not more than 1 mm. In the particular case of the technical solution, a material containing silver and / or its compounds, or containing iodine and / or its compounds, or containing chlorine and / or its compounds, or containing fluorine and / or its compounds can be used as a bactericidal material, or material containing benzalkonium chloride. It is also possible to use a sorbent with bactericidal properties as a bactericidal material.

The inventive bactericidal device comprises a housing provided with at least one fitting and a filter element, and differs from known devices in that the filter element is made of a filter material comprising a porous base and a bactericidal material. As a porous base, a filter film made of a polymeric material, such as a track membrane or similar material, is used, and the bactericidal material is made in the form of an additional layer placed on at least one of the filtering surfaces of the film. In the particular case of execution, the housing of the device is equipped with an outlet fitting, and the filter element is placed outside the housing, at least on one of its bearing surfaces and is hermetically connected to the indicated surfaces around the perimeter. In the particular case of the implementation of such a device, recommended for use, in particular for pressure-free filtration of liquids, its body is preferably flat. The bearing surface of the housing, it is advisable to provide channels for collecting filtered fluid and drainage of the filtrate.

Another particular case of the claimed bactericidal device is a device for cleaning liquids sent to filter under pressure. The device comprises a detachable housing and a filter element made of the above filter

material. The filter element is made in the form of a filter cartridge and is tightly attached around its perimeter to the surface of the supporting frame, preferably of cylindrical shape. The filter cartridge is installed in the housing with a tight connection of the ends of the filter cartridge with the adjacent parts of the inner surface of the housing and with the possibility of removing the filter cartridge from the housing, one of the detachable parts of the housing being provided with inlet and outlet fittings for supplying untreated liquid and for removing the filtrate, respectively through holes and a flow channel for draining the filtrate to the outlet fitting.

The technical result of the proposed solutions is the creation of filter material with high filtering characteristics, bactericidal properties and stable bacteriostatic action, as well as the development of a bactericidal device that provides effective cleaning of liquids and gases not only from suspensions and chemical compounds, but also from bacteria. The thickness of the layer of bactericidal material (not more than 1 mm) placed on the filtering surface of the track membrane, the pore size dispersion of which is 2-3%, limits the contact time of the filtered medium with the bactericide during the filtration process, as a result of which the bactericide concentration in the filtrate decreases to values noticeably lower MPC.

On figa and 1b shows a longitudinal section of a filter material.

Figure 2 presents a longitudinal section of a bactericidal device with a flat body.

Figure 3 presents a diagram of the operation of the apparatus for cleaning liquid under the influence of gravity (pressureless filtration).

Figure 4 presents a longitudinal section of a bactericidal device for cleaning liquid directed under pressure.

The filter material contains a track membrane 1 and a bactericidal material 2. The bactericidal device comprises a housing 3, a filter element 4 made of filter material including a track membrane 1 and a bactericidal material 2, an outlet fitting 5, an inlet fitting 6, a supporting frame 7.

The bactericidal device shown in FIG. 2 operates as follows (illustrated in FIG. 3). The device, to the outlet nozzle 5 of which the drain hose is connected, is immersed in the intake tank 8 with crude liquid, so that the liquid covers the filter element 4, preferably completely, the free end of the drain hose is lowered into the filtrate collection vessel 9, which is lower than the intake tank 8 A light suction through the free end of the drain hose starts the filtering process. Under the action of gravity, the liquid through the filter element 4 through the channels for collecting the filtered liquid and the filtrate outlet, made in the housing 3, enters through the outlet nozzle 5 through the drain hose into the container for collecting the filtrate 9. When the filtering process is carried out in a pressureless mode, the pressure drop across the filter element 4 created due to the height difference between the intake tank 8 and the container for collecting the filtrate 9, i.e. by creating a vacuum in the filtration zone.

In the particular case of the implementation of a bactericidal device for cleaning liquid directed under pressure (figure 4), the housing 3 is made detachable. The lower detachable part of the housing 3 is equipped with an inlet fitting 6 and an outlet fitting 5. The filter element 4 is made in the form of a filter cartridge. The supporting frame 7 is made in the form of a cylinder, on the surface of which a filter element 4 is hermetically fixed around its perimeter, and is equipped with through holes and a flow channel for draining the filtrate to the outlet fitting 5. The bactericidal device operates as follows. The crude liquid enters through the nozzle 6 into the housing 3, is filtered through a filter element 4, and then through

through holes in the flow channel for collecting the filtered fluid and drainage of the filtrate, made in the supporting frame 7, enters the outlet fitting 5, from where it is discharged through a drain hose into a container for collecting the filtrate (not shown in Fig. 4).

Empirically established the following. When purifying drinking water, the process is recommended to be carried out in periodic mode, interrupting the filtration every time after receiving the next ~ 15 l of purified liquid for a period of 1 to 1.5 hours. This time was sufficient to achieve the concentration of bactericide in the filtrate, necessary for the death of the detained bacteria.

A bactericidal device with the described filter material can be used, in particular, in domestic systems for the production of drinking water to increase its purification efficiency. It is possible to use filter material in installations for treating water from wells or wells.

Claims (18)

1. A filter material comprising a porous base and a material with bactericidal properties, characterized in that as a porous base, a filter film made of a polymeric material such as a track membrane or similar material is used, and the material with bactericidal properties is made in the form of an additional layer placed at least on one of the filter surfaces of the film. 2. The material according to claim 1, characterized in that the thickness of the filter film is preferably 7-25 microns, and the diameter of the through pores is from 0.05 to 0.4 microns. 3. The material according to claim 1, characterized in that the thickness of the additional layer does not exceed 1 mm 4. The material according to claim 2, characterized in that the thickness of the additional layer does not exceed 1 mm 5. Material according to any one of claims 1 to 4, characterized in that a material containing silver and / or its compounds is used as a material with bactericidal properties. 6. The material according to any one of claims 1 to 4, characterized in that a material containing iodine and / or its compounds is used as a material with bactericidal properties. 7. Material according to any one of claims 1 to 4, characterized in that a material containing chlorine and / or its compounds is used as a material with bactericidal properties. 8. The material according to any one of claims 1 to 4, characterized in that a material containing fluorine and / or its compounds is used as a material with bactericidal properties. 9. The material according to any one of claims 1 to 4, characterized in that a bactericidal sorbent is used as a material with bactericidal properties. 10. The material according to any one of claims 1 to 4, characterized in that a material containing benzalkonium chloride is used as a material with bactericidal properties. 11. A bactericidal device, comprising a housing provided with at least one fitting, and a filter element, characterized in that the filter element is made of a filter material comprising a porous base and a material with bactericidal properties, with a polymer film filter film being used as a porous base material, such as a track membrane or similar material, and material with bactericidal properties is made in the form of an additional layer placed at least on one of the filter erhnostey film. 12. The device according to claim 11, characterized in that the thickness of the filter film is preferably 7-25 microns, and the diameter of the through pores is from 0.05 to 0.4 microns. 13. The device according to claim 11, characterized in that the thickness of the additional layer does not exceed 1 mm 14. The device according to p. 12, characterized in that the thickness of the additional layer does not exceed 1 mm 15. The device according to any one of paragraphs.11-14, characterized in that the housing is equipped with an outlet fitting, and the filter element is placed outside the housing, at least on one of its bearing surfaces and is hermetically connected to the indicated surfaces around the perimeter. 16. The device according to p. 15, characterized in that the housing is preferably flat. 17. The device according to clause 16, characterized in that the bearing surface of the housing is equipped with channels for collecting filtered fluid and drainage of the filtrate. 18. The device according to claim 11 for cleaning liquids directed under pressure, characterized in that the housing is detachable, the filter element is made in the form of a filter cartridge and is attached tightly around its perimeter to the surface of the supporting frame, preferably of cylindrical shape, the filter cartridge is installed in a housing with a sealed connecting the ends of the filter cartridge with adjacent parts of the inner surface of the housing and with the possibility of removing the filter cartridge from the housing, one of the detachable parts of the housing It is provided with inlet and outlet fittings for supplying untreated liquid and discharging the filtrate, respectively, and the supporting frame is provided with through holes and a flow channel for draining the filtrate to the outlet fitting.