RU64926U1 - FILTER FOR CLEANING DRINKING WATER (OPTIONS) - Google Patents

Abstract

The filter for drinking water purification contains a cylindrical body with a layer of granular sorbent with grain sizes of 1-3 mm and a filter element in the form of hollow mesh cylinders with a mesh hole size of 0.8 mm. The implementation of the housing with a ratio of diameter to height of at least 1/3 makes it possible to obtain an increased filtration rate. The supply of filtered water from top to bottom eliminates the possibility of air congestion, which ensures uninterrupted operation of the filter. In the filters for water supply systems in the lower part of the housing there is a drainage granular element with grain sizes of 3-5 mm, and a washing system for a granular sorbent is installed. The inventive filter can be used for purification of drinking water in a domestic environment (1st option) and for water purification in water supply systems (2nd option).

Description

The utility model relates to filtering devices with granular loading and can be used to purify drinking water in households and water supply systems.

The prior art device for water purification, comprising a housing in which three filters are arranged in series: the first filter to remove large particles from the stream, the second filter from activated carbon for adsorption of organic impurities and the third ceramic filter containing silver for bacteria - static action while the inlet and outlet pipes are located on the same longitudinal axis (EPO, z. No. 0150559, class B01D 29/26, publ. 07.08.85).

The disadvantage of this device is the design complexity and large weight and dimensions for a given performance, as well as the use of several types of sorption and filter materials.

A known filter for the purification of drinking water coming from centralized water supply systems from harmful impurities is able to provide purification from suspended particles of iron, aluminum, cadmium, cesium, molybdenum, copper, zinc, lead, chromium. The material of the filter element in this filter is ceramics (V. A. Mukhin, N. N. Smirnova “Investigation of the process of heat and mass transfer during filtration in porous media”, Preprint 26-28, Novosibirsk, 198 p.).

The disadvantage of this device is the limited service life due to the fact that the filter is clogged by colloids in water. These colloids, the main component of which are gels of various nature, serve as a good sorbent of impurities of organic and inorganic origin and, ultimately, contribute to the rapid pollution of filters and their failure.

The closest technical solution to the claimed one for the first option is a device for drinking water purification in domestic conditions, containing a cylindrical body with inlet and outlet nozzles for supplying and discharging filtered water, a layer of granular sorbent in the form of activated carbon placed inside the housing, a filter element in the form kapron mesh, the bounding layer of the sorbent on both sides, a pipe connected to the outlet pipe and passing through the sorbent layer. In this case, the inlet and outlet nozzles are installed in the bottom of the housing (RU, p. 94023653, B01D 15/04).

The disadvantage of this device is the complexity of the design and maintenance, as well as low productivity due to low

water filtration rate, due to the small ratio of the diameter of the casing to its height, as well as due to the possibility of an air plug that slows down or stops the filtration process with the formation of a dead zone as a result of a lower supply of filtered water.

The closest technical solution to the claimed one according to the second embodiment is a filter for water purification for centralized water supply, comprising a cylindrical body with a conical bottom, a spherical cover, a granular sorbent inside the body, a filter element made in the form of a porous ring mounted in a chamber fixed in the body, and a drainage element in the form of pipes of a porous material, for example, sintered titanium powder. In addition, the filter contains inlet and outlet nozzles for supplying and discharging filtered water, installed, respectively, in the lower part of the housing and in the upper, and inlet and outlet nozzles for supplying and discharging washing water, installed, respectively, in the cover of the housing and the lower part housing (RU, p. 1223957, B01D 23/10).

The disadvantages of this device are similar to the disadvantages of the prototype for the first option.

The technical result of this technical solution is to simplify the design of the filter and its maintenance, as well as to increase the period of uninterrupted operation of the filter by eliminating dead zones during filtration.

The technical result is achieved by the fact that the filter for drinking water purification contains a cylindrical body with inlet and outlet nozzles and a cover, a layer of granular sorbent inside the body, a filter element and a pipe passing through the sorbent layer, while the body is made with a diameter to height ratio of at least 1/3, a filter element in the form of hollow mesh cylinders with a fitting and with a mesh hole size of 0.8 mm, and a granular sorbent with grain sizes of 1-3 mm.

In addition, the filter element consists of two hollow mesh cylinders, one of which is connected to the inlet pipe, and the second to the lower end of the pipe.

In addition, the filter element consists of three hollow mesh cylinders, two of which are connected to each other and to the lower end of the pipe, and the third to the inlet pipe.

In addition, the housing cover is made flat or spherical, the bottom of the housing is protruding beyond the walls of the housing or flush with the wall of the housing, and the inlet and outlet nozzles are installed in the cover.

The filter for drinking water purification contains a cylindrical body with a cover and a layer of granular sorbent, inlet and outlet nozzles for supply and discharge

filtered water, inlet and outlet nozzles for supplying and discharging washing water for a granular sorbent, a filtering element and a drainage element, the housing being made with a diameter to height ratio of at least 1/3, the filtering element in the form of hollow mesh cylinders with a fitting and with dimensions mesh holes 0.8 mm, and a drainage element in the form of a granular sorbent with grain sizes of 3-5 mm.

In addition, filter elements with inlet and outlet nozzles for supplying and discharging filtered water and inlet and outlet nozzles for supplying and discharging washing water are installed in the cover and bottom of the housing or in the upper and lower parts of the housing.

The implementation of the design of the housing with a ratio of the diameter of the housing to its height of at least 1/3 makes it possible to obtain an increased filtration rate, and the top supply of filtered water eliminates the possibility of an air plug that contributes to interruption of filtration, which ultimately ensures uninterrupted operation of the filter.

The simplicity of the design and maintenance of the filter is ensured by the implementation of the filter element in the form of hollow mesh cylinders connected to the inlet and outlet nozzles for supplying and discharging filtered water, and with the inlet and outlet nozzles for supplying and discharging the wash water, and the presence of a drainage element in the form of a sorbent with grain sizes of 3-10 mm, which does not require any supporting elements.

In figures 1, 2, 3, filters are given for the 1st embodiment.

Figure 4 - filter element.

In Fig.5, 6, 7, 8, 9 - filters for the 2nd option.

The filter for water purification in domestic conditions for the first option (Figs. 1, 2, 3) consists of a cylindrical body 1 with a cover 2, an input 3 and an output 4 nozzles installed in the cover. The case is made with a diameter of 100 mm and a height of 300 mm. Inside the housing 1 there is a granular sorbent 5, for example zeolite, with grain sizes of 1-3 mm, and a pipe 6 connected by its upper end to the outlet pipe 4, and the lower end with a filter element 7. The filter element 7 is made in the form of two (Fig. 1 , 2) or three (FIG. 3) hollow mesh cylinders 8 with a fitting 9 (FIG. 4) and with a mesh hole size of 0.8 mm. The inlet pipe 3 and the lower end of the pipe 6 are connected to the filtering elements 7 by means of a fitting 9. The housing cover can be made flat (Fig. 1, Fig. 3) or spherical (Fig. 2), and the bottom of the housing protrudes beyond the walls of the housing (Fig. 3) or flush with the wall (figure 1, 2).

The filter according to the first embodiment works as follows.

Purified water from the pipeline (not shown in Fig.) Through the inlet pipe 3 connected to the filter element 7 enters the housing 1. The filter element 7 on the inlet pipe 3 plays a passive role, it only prevents the sorbent from spilling out of the housing. In the housing 1, water is filtered from top to bottom through a layer of pre-washed granular sorbent 5 and then through a filter element 7 connected to the inlet 4. In this filter element, purified water is selected, while the mesh hollow cylinder 8 with a mesh hole size of 0.8 mm does not pass particles of a sorbent having a large dimension of 1-3 mm The purified water through the outlet pipe 4 enters the consumer.

The performance of this filter is 60 l / h with a case diameter of 100-150 mm and a height of 300-450 mm.

The filter for water purification in centralized water supply systems for the second embodiment comprises a cylindrical body 1 with a cover 2, inlet 3 and outlet 4 nozzles for supplying and discharging filtered water, inlet 5 and outlet 6 nozzles for supplying and discharging washing water. A granular sorbent 7, for example, zeolite, with grain sizes of 1-3 mm is placed in the housing 1. The ratio of the diameter of the casing to its height should be at least 1/3, since in the case of a larger ratio, not all of the sorbent works over the entire area, and dead zones form. The filter element 7 ^{a is} made in the form of a hollow mesh cylinders 8 with a fitting 9 and with a mesh size of 0.8 mm (Fig. 4). In the lower part of the housing 1 there is a drainage element 10 in the form of a granular sorbent - zeolite with grain sizes of 3-5 mm. The filtering elements 7 ^{a are} connected to the inlet 3 and outlet 4 nozzles for supplying and discharging filtered water and to the inlet 5 and outlet 6 nozzles for supplying and discharging washing water and are installed in the cover 2 (with nozzles 3, 6) of housing 1 and the bottom (with nozzles 4, 5) (Figs. 5, 6) .. The cylinder body is mounted on supports 11. For ease of installation, in case of height limitations, nozzles 3, 6 are installed in the upper part of the body, and nozzles 4, 5 in its lower part ( Fig.7). The cover and the bottom of the housing can be made flat (figure 5, 7) or, in the case of the filter at high pressure, spherical (figure 6).

For filters with high performance -> 500 l / h the filter is made with conical upper and lower parts of the housing (Fig. 8, 9).

The filter according to the second embodiment works as follows.

The purified water through the inlet pipe 3 with the filtering element 7 enters the housing 1, in which, passing through the pre-cleaned sorbent 7 - zeolite, it is purified over the entire area of the housing. The filter element 7 ^a connected to the outlet pipe 4 for drainage of filtered water, and a drainage granular sorbent 10

delay the fine fraction of the sorbent 7 and pass the purified water, which through the outlet pipe 4 enters the consumer. For washing the sorbent 7, the inlet 3 and outlet 4 nozzles for supplying and discharging the filtered water are closed, and the inlet 5 and outlet 6 nozzles for supplying and discharging the washing water are opened.

Industrial testing of the claimed filter in water supply systems and at home with normal and elevated pressure has shown positive results in the quality purification of drinking water of varying degrees of pollution, which, according to the authors, will ensure widespread industrial use of the claimed filter.

Claims (8)

1. A filter for drinking water purification, comprising a cylindrical body with inlet and outlet nozzles and a cover, a layer of granular sorbent inside the body, a filter element and a pipe passing through the sorbent layer, characterized in that the body is made with a diameter to height ratio of at least 1 / 3, a filter element in the form of hollow mesh cylinders with a fitting and with a mesh hole size of 0.8 mm, and a granular sorbent with grain sizes of 1-3 mm. 2. The filter according to claim 1, characterized in that the filter element consists of two hollow mesh cylinders, one of which is connected to the inlet pipe, and the second to the lower end of the pipe. 3. The filter according to claim 1, characterized in that the filter element consists of three hollow mesh cylinders, two of which are connected to each other and to the lower end of the pipe, and the third to the inlet pipe. 4. The filter according to claim 1, characterized in that the housing cover is made flat or spherical. 5. The filter according to claim 1, characterized in that the bottom of the housing is made in the form of protruding beyond the walls of the housing or flush with the wall of the housing. 6. The filter according to claim 1, characterized in that the inlet and outlet nozzles are installed in the cover. 7. A filter for drinking water purification, comprising a cylindrical body with a lid and a layer of granular sorbent, an inlet and outlet pipe for supplying and discharging filtered water, an inlet and outlet pipe for supplying and discharging washing water for a granular sorbent, a filter element and a drainage element, characterized the case is made with a diameter to height ratio of at least 1/3, a filter element in the form of hollow mesh cylinders with a fitting and a mesh hole size of 0.8 mm, and a drainage element in the form of a granular sorbent with dimensions Eren 3-5 mm. 8. The filter according to claim 7, characterized in that the filter elements with inlet and outlet nozzles for supplying and discharging filtered water and inlet and outlet nozzles for supplying and discharging washing water are installed in the lid and bottom of the housing or in the upper and lower part of the housing.