RU4490U1 - DEVICE FOR CLEANING AND DISINFECTING WATER - Google Patents

Abstract

1. Device for cleaning and disinfecting water, including a cylindrical body, in which between the receiving part and the output part there are several stages of cleaning, absorption and disinfection with the corresponding elements, characterized in that the first cleaning stage located in the receiving part is made in the form of a coil, the axis the symmetry of which is located on the axis of symmetry of the cylindrical body, and the coil has an internal channel located along the axis passing through the flange of the coil adjacent to the element ntam of the next stage, and its other flange overlaps the said channel, while the latter is communicated through holes and / or slots made in the connecting flanges of the coil part or the passages of this part with a volume limited by the flanges of the coil and the inner part of the cylindrical body, in addition, part of the coil the flanges connecting it are surrounded by filtering material, and through holes and / or slots are made in the receiving part of the housing located between the coil flanges. 2. The device according to claim 1, characterized in that the filter material consists of fibers containing activated carbon wound around a part connecting the flanges of the coil. The device according to claim 2, characterized in that the filter material has a porosity of 0.4 cm / g. 4. The device according to claim 1, characterized in that between the first cleaning stage and the output part of the housing there is a disinfection stage and an activated carbon absorption stage containing perforated cylindrical inserts at the ends of which the cylindrical absorption stage inserts and the first stage insert are both

Description

Device for cleaning and disinfecting water.

The utility model relates to the constructive implementation of water purification and disinfection, used mainly in the field to produce drinking water from unequipped sources.

A device comprising a plastic tube, inside which is placed an inlet filter of a porous material, a layer of polyhaloid ion-exchange resin, an intermediate filter of a porous polymeric material, an output filter of a porous polymeric material and a mouthpiece / 1 /.

Such a device makes it possible to disinfect water from microorganisms rather effectively and to some extent cleans it of mechanical impurities. Thus, with continuous passage of river water through this device with an initial infection with Escherichia coli 10 microbial cells / l and a content of mechanical impurities of 60-100 mg / l at the outlet devices receive water with an infection of about 100 microbial cells / l and an impurity content of 40-70 mg / l.

Such parameters are clearly insufficient, in addition, the device has a low throughput from non-equipped sources containing a significant amount of micro suspensions of organic and inorganic origin. On average, the throughput of such a device does not exceed 10-15 liters, which is insufficient both from the point of view of the operation of the device and in terms of cost per liter of water. Moreover, according to GOST-2874-82, the content of Escherichia coli in water should not exceed 3 microbial cells / liter, which is also not provided by this device. by the swarm.

Closest to the claimed is a device for cleaning and disinfecting water, including a cylindrical body, in which between

M.C. B01024 / 08

the receiving part and the output part are several stages of cleaning, absorption and disinfection with the corresponding elements / 2 /. In this case, the casing is made of a polymer tube, on one side of which an inlet filter is installed, and on the other, a tubular mouthpiece and between them are placed disinfecting material, material containing activated carbon and bactericidal material, through separating porous gaskets.

These devices allow improving the cleaning and disinfection parameters by almost an order of magnitude, but this also turns out to be insufficient, in addition, the total volume of water being treated has not changed.

Recently, the requirements for water purification and disinfecting devices have become stricter in terms of increasing the amount of disinfected water (at least 25-30 l) and improving the quality of cleaning from organic impurities .. This is due to the need to increase the duration of use of one device / about 7 days at 5- 7 liters of consumption / and the need to purify water from unequipped sources from dissolved toxic substances, among which in the first place are organohalogen compounds / products of chemical transformations estitsidov /.

The technical result achieved by using this utility model is to increase the throughput and the degree of purification of water from toxic organic impurities while maintaining a high water passage rate, effective disinfection of microorganisms and a high degree of purification from mechanical impurities and ensuring a low disinfectant content in water.

The indicated problem solved by this utility model is achieved due to the fact that the first cleaning stage located in the receiving part is made in the form of a coil, the symmetry axis of which is located along the symmetry axis of the cylindrical body, moreover, the coil has an internal

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a channel located along the axis, passing through the coil flange adjacent to the elements of the next stage, and its other flange overlaps the channel, while the latter is communicated through holes and / or slots made in the connecting flanges of the coil part or the passages of this part with the volume bounded by the flanges of the coil and the inner part of the cylindrical body, in addition, the part of the coil connecting its flanges is surrounded by filter material, and in the receiving part of the body located between the flanges of the coil Through holes and / or slots are provided.

And also due to the fact that the filter material consists of fibers containing activated carbon wound around the part connecting the coil flanges, and the filter material has a porosity of 0.4.

Moreover, between the first cleaning stage and the output part of the casing there is a disinfection stage and, containing activated carbon, an absorption stage, on the ends of which perforated cylindrical inserts are installed, and the cylindrical absorption stage inserts and the first disinfection stage insert adjacent to the first cleaning stage are fixed and the second disinfection stage insert is installed with the possibility of movement along the axis of symmetry of the cylindrical body and spring-loaded relative to etstvuyuschey insertion absorption stage via a spring element.

In addition, the spring element is made of a spiral polymer or twisted material containing activated carbon, and the volume enclosed between the inner surface of the cylindrical body and adjacent inserts of the disinfection stage and the absorption stage is 20-100% of the volume of the absorption stage.

Moreover, the ratio between the volumes of the disinfection and absorption steps is from 5: 4 to 2: 1, and the quality of activated carbon

absorption steps use activated lignin carbon with a grain size of 0.5 to 1.5 mm.

In addition, one of the steps is made in the form of a sterilization step in which there is at least one intermediate layer of activated carbon fibers. Moreover, the sterilization step is installed between the corresponding insert of the absorption step and the end of the outlet part of the housing, and between the end of the sterilization step and the end of the output part of the housing is a perforated cylindrical insert.

And each of the said inserts is made in the form of a pot and has a permeable bottom and is installed without contact of the bottom with the element 1u {and the corresponding step, moreover, the space bounded by the bottom of the pot, its walls and the surface of the corresponding adjacent step is filled with activated carbon fibers, while , a nozzle is installed at the end of the output part of the housing.

A search conducted on patent technical literature showed that the claimed combination is unknown, i.e. it meets the condition of patentability novelty.

Since the claimed utility model is made from known components, it meets the patentability condition of industrial applicability.

Figure 1 presents a longitudinal section of the claimed utility model, Figure 2 is a sectional view of a perforated cylindrical insert, and Figure 3 is a longitudinal section of the elements of the first filtration stage.

A device for cleaning and disinfecting water includes a cylindrical body 1, for example, in the form of a polymer tube in which several stages of water treatment are installed, including a disinfection stage 2, including a layer of disinfecting ion-exchange resin and a stage of

- 4 glosses 3. Containing activated carbon. The mentioned steps at the ends have cylindrical inserts 4 / 4a, 4b, 4c, 4d, 4e /, which have a side surface 5 and are filled. For example, activated carbon fibers, in addition, cylindrical inserts can be made in the form of pots. One of the steps is made in the form of a sterilization step and is a bactericidal material 7 / including, for example, a layer of activated carbon-containing fibers / and a gasket 8, moreover, this layer is located between inserts 4a and 4b, the latter being related to the absorption step, and 4a is the last insert at the output end of the housing 1. The inserts 4c, 4c and 4 e are fixed rigidly relative to the housing, and the insert 4 d is axially movable, and a spring element 9 is installed between the inserts 4c and 4 d, which can be made of cn an oral polymer or a twisted material containing activated carbon. The first cleaning stage is located in the receiving part of the housing 1, which is made in the form of an inlet filter 10 in the form of a coil on which filtering material 11 is wound, consisting of activated carbon fibers including them. 1, a nozzle is installed in the form of a mouthpiece 12. In the inserts 4, perforations 13 are made, for example, in the form of holes. The cleaning stages are fixed near the lower end 15 of the housing 1 by means of an inlet filter 10 of the first cleaning stage and near the end face 16 by means of the mouthpiece 12. The side part 1 of the housing 1 in the area of the inlet filter 10 forms a volume 18 limited by the flanges 19,20 of the coil 10, which is communicated through the through holes and / or slots 21 made in the side part 17 with the external environment. 10 has an internal channel 22, which through holes and / or slots or passages 23 communicates with the volume 18. In this case, the internal channel 22 can be formed by elements 24, which connect the flanges 19 and 20 together with the input coil 10

filter, for example, the elements 24 can be made in the form of corresponding parallel pins, the ends of which are pressed into the flanges 19 and EO. Moreover, the filter material has a porosity of 0.4. Activated lignin carbon with a grain size is used as activated carbon in the absorption stage 3 from 0.5 to 1.5 mm. The volume enclosed between the inner surface of the cylindrical body 1 and the adjacent inserts 4 of the disinfection step 2 and the absorption step 3 is 20-100% of the volume of the absorption step Z. The ratio between the volumes of the disinfection steps 2 and absorption 3 is from 5: 4 to 2: 1.A the filter material has a porosity of 0.4.

The device operates as follows.

The end face 15 of the receiving part of the housing 1 of the device is immersed in water from an unequipped source, which can be used by any body of water. From the side of the nozzle-mouthpiece 12 create a vacuum. Water through the stage of filtration-inlet filter 10 enters the cavity of the housing 1, in volume 18, where it is cleaned from mechanical impurities, moreover, the use of the side part 17 of the housing for water passage

1 allows you to significantly increase the contact area of the filter with water, i.e. increase the filtration area, which increases the durability of the inlet filter 10. After passing through the filter material 11, the water purified from coarse mechanical impurities enters the disinfection stage

2, which can be used as an ion-exchange resin and then, when passing through the absorption stage 3 containing activated carbon, the absorption of dissolved in the form of substances is carried out, this improves the taste of the purified water, in addition, the level of residual iodine in the purified water / or other element decreases depending on the ion-exchange resin used. The spring element 9 maintains the decontamination step in a dense state and does not allow its particles to move from

X // f //

- b water flow, to form channels for the passage of water without the proper degree of disinfection. After that, the water passes through the sterilization stage with bactericidal material 7, moreover, the gaskets 8 allow you to normalize the water flow and additionally filter and absorb substances dissolved in water. With an increase in the number of gaskets 8 the quality of cleaning increases. Next, the water enters the nozzle 12. It is ready for use.

The performance of this device was checked by its capacity, the degree of purification of water from toxic organic and mechanical impurities, the effectiveness of disinfection and the rate of passage of water through the device and the disinfectant content in the treated water. To determine the throughput through the device using a pump that creates a vacuum of 0, 2 atm was passed 0.5 l per day of river water with an initial pre-predisposition of catarrhal bacillus of 10 m cells / liter and contamination with mechanical particles of 60 mg / l . Throughput is defined as the amount of water passed through to reduce the initial speed of water through the device by a factor of three. The disinfection efficiency is determined by the content of E. coli in purified water. According to the requirement of GOST 2874-82 when the content of E. coli is more than 3 m cells / l, water is considered unsuitable for The degree of purification from mechanical impurities is estimated by the transmittance of mechanical impurities, defined as the ratio of the content of impurities in purified water to the content of Eames in the original. The speed of water passage through the device is estimated by the amount of water / in ml / passed through the device in 1 minute with a pressure difference at the inlet and outlet of the device equal to 0.2 atm. The disinfectant content in the passed water when using a polyiodine anion exchange resin is ottenirovat by the content Yolg1.When the content of iodine is higher than A mg / l in

- 7, it becomes an unpleasant hall and becomes unfit for drinking. The degree of purification of water from toxic organic impurities was evaluated by the percentage of the concentrations of these impurities in water before and after it passed through the device.

The operability of the device is illustrated by the following example: In a polymer tube with a length of 200 mm and an inner diameter of 10 mm, the polymer nets of all filters are equipped with carbon fiber material. As an input stage 10, a coil with carbon fiber material 11 is used. Its height is 25 mm or 12% of the length devices. The ratio of the layers of the polyiodine resin SIA-1 / TU-64-2-381-87 / and activated lignin coal, i.e. layers of steps 2 and 3 separated by perforated cylindrical inserts 4 is 3: 2.8 a silver-containing cation exchange resin with a content of silver ions of 8.5 mEq / l and a granulometric composition of 0.5-1.2 mm and four layers of gaskets of containing activated carbon fibers, the height of the output part is 10 mm or 5% of the length of the device.

The throughput of such a device is 25 l, the content of E. coli in purified water is less than 3 m cells / l, the transmittance of mechanical particles is 10%, the rate of water passage through the device is 125 ml / min, the iodine content in the passed water is 2, 5 mg / l.

Sources of information:

1. U.S. Patent No. 4,298,475, CL B01024 / 08, 1981.

2. U.S. Patent No. 4,995,976, CL B01024 / 08, 1991.

Claims (12)

1. Device for cleaning and disinfecting water, including a cylindrical body, in which between the receiving part and the output part there are several stages of cleaning, absorption and disinfection with the corresponding elements, characterized in that the first cleaning stage located in the receiving part is made in the form of a coil, the axis the symmetry of which is located on the axis of symmetry of the cylindrical body, and the coil has an internal channel located along the axis passing through the flange of the coil adjacent to the element ntam of the next stage, and its other flange overlaps the said channel, while the latter is communicated through holes and / or slots made in the connecting flanges of the coil part or the passages of this part with a volume limited by the flanges of the coil and the inner part of the cylindrical body, in addition, part of the coil the flanges connecting it are surrounded by filtering material, and through holes and / or slots are made in the receiving part of the housing located between the coil flanges.  2. The device according to claim 1, characterized in that the filter material consists of activated carbon-containing fibers wound around a part connecting the flanges of the coil. 3. The device according to claim 2, characterized in that the filter material has a porosity of 0.4 cm ³ / g.  4. The device according to claim 1, characterized in that between the first cleaning stage and the output part of the housing there is a disinfection step and an activated carbon absorption stage containing perforated cylindrical inserts at the ends of which the cylindrical absorption stage inserts and the first disinfection step insert are adjacent to the first cleaning stage, are installed motionlessly, and the second insert of the disinfection stage is installed with the possibility of movement along the symmetry axis of the cylindrical body and is spring loaded with respect to the corresponding insert of the absorption stage by means of a spring element.  5. The device according to claim 4, characterized in that the spring element is made of a spiral polymer or twisted material containing activated carbon.  6. The device according to claim 4, characterized in that the volume enclosed between the inner surface of the cylindrical body and adjacent inserts of the disinfection step and the absorption step is 20-100% of the volume of the absorption step.  7. The device according to claims 1 and 4, characterized in that the ratio between the volumes of the disinfection and absorption steps is 5: 4 - 2: 1.  8. The device according to claims 1 and 4, characterized in that the activated carbon of the absorption step uses activated lignin carbon with a grain size of 0.5-1.5 mm.  9. The device according to claims 1 and 4, characterized in that one of the steps is made in the form of a sterilization step, in which there is at least one intermediate layer of activated carbon-containing fibers, the sterilization step being installed between the corresponding insert of the absorption step and the end of the outlet body parts.  10. The device according to PP.4 and 9, characterized in that between the end of the sterilization stage and the end of the output part of the housing is a perforated cylindrical insert.  11. The device according to PP.4 and 10, characterized in that each of the said inserts is made in the form of a pot, has a permeable bottom and is installed without contact of the bottom with elements of the corresponding step, and the space bounded by the bottom of the pot, its walls and the surface of the adjacent steps to it, filled with activated carbon fibers. 12. The device according to claim 1, characterized in that a nozzle is installed at the end of the output part of the housing.