RU2124921C1 - Canister for disinfection of potable water - Google Patents

Abstract

FIELD: purification and disinfection of potable water. SUBSTANCE: the canister has a casing, cover with a pipe connection and ducts for passage of disinfected water, device for feeding the source water in the direction from bottom to top having a water dissector with a shoulder. Installed in the lower and upper parts of this device are grids with fibrous cation-exchange materials located on their both sides, and antiseptic material is placed between the grids. EFFECT: reduced dimensions and cost of the canister, enhanced efficiency of operation. 5 cl, 3 dwg

Description

 The invention relates to a device for producing safe drinking water from bacteria and viruses and can be used as a replaceable cartridge for disinfecting drinking water.

 Known cartridge for improving the quality of drinking water, consisting of a cylindrical or truncated cone-shaped body with ion-exchange resin and / or activated carbon and, if necessary, bacteriostatic active substance inserted into the device for flowing under gravity, the upper and lower end walls of which contain inlet and outlet openings, consisting of a large number of narrow slots in the end walls (German Patent N 3535677, B 01 D 23/28).

 However, this cartridge does not disinfect water from bacteria, viruses and helminths even when operating within a resource of 250-300 liters, which is insufficient both in terms of cartridge service and in terms of the cost of obtaining 1 liter of safe drinking water.

 The closest in technical essence and the achieved effect is a filter cartridge for disinfecting drinking water, for example tap water, spring or well (RF Patent N 2048856, B 01 D 24/10).

 The cartridge consists of a housing with a flange, and carbon sorbent and bactericidal materials are placed inside the housing between the perforated partitions. The cartridge along the water includes successive layers of fibrous carbon sorbent material, fiber cation exchange material, iodine-containing strongly basic ion exchange resin, fiber cation exchange material, fiber carbon sorbent material, carbon sorbent material and silver-containing material with a volumetric ratio of layers: 2.1: 1: 2, 5: 1: 1.4: 6: 3 - 1.4: 0.5: 3: 1: 2.1: 4: 5.

Carbon sorbent material consists of granules with a size of 0.3 - 1.0 mm or fibers with a weight of at least 500 g / m ² .

The iodine-containing strongly basic ion-exchange resin has a particle size distribution of 0.3 - 1.0 mm. In addition, the cartridge contains: a silver-containing sorbent material, which is a silver-impregnated carbon sorbent with a total pore surface of at least 1100 m ² / g, a micropore volume of at least 0.4 m ³ / g and a silver-containing material, which is a granular or fiber cation exchange material with a bulk capacity of at least 2.0 mmol / g, containing Ag ⁺ as the counterion.

 Studies have shown that this filter cartridge has an insufficient initial filtration rate of 150 - 155 m / min, and when cleaning and disinfecting water with a solids content of more than 5 mg / l, the upper layer of fiber carbon sorbent material becomes clogged, and the water filtration rate decreases through the cartridge and the cartridge stops working with a resource of 300 - 350 liters.

 The aim of the invention is to eliminate the above disadvantages, namely the creation of a cartridge for disinfection of drinking water, providing a filtration rate of at least 1 l / min and disinfection of at least 5000 l of water.

This goal is achieved by the fact that in the proposed cartridge for disinfection of drinking water containing a housing, perforated partitions, layers of carbon fiber and fiber cation exchange material, a bactericidal material, the housing is equipped with a removable bottom, and in the upper part of the housing there is a lid with a fitting and channels for passing the disinfected water, and the lid is equipped with a device for supplying water to the bottom, mounted in the housing coaxially or offset from its axis, in addition, the cartridge is equipped with wives a water divider, which is placed inside the device for providing water supply and has a shoulder, and the partitions are made in the form of gratings located in the lower and upper parts of the device for providing water supply, the fiber material being located on both sides of the lower and upper gratings, and the bactericidal material located between the gratings, on both sides of which fiber carbon material is placed. In addition, the bactericidal material is a polyhaloid anion exchange resin with a particle size distribution of 0.2 - 1.5 mm, the carbon fiber material is a fiber with a weight of at least 400 g / m ² , and the fiber cation exchange material has a bulk capacity of at least 4 mg equiv / g, while the cartridge along the water includes sequentially arranged layers of fiber carbon material, polyhaloid anion exchange resin, fiber carbon material and fiber cation exchange material with a volumetric ratio enii layers: (1.5: 3.5: 0.5: 1.5 - 1: 4.5: 1: 0.5).

 Thus, a comparative analysis of the proposed cartridge with the prototype showed that the proposed technical solution meets the criterion of "novelty." And since the use of this cartridge for disinfecting drinking water has a new effect, which is expressed in a significant increase in productivity and resource and the possibility of using this disinfecting cartridge in any device for producing high-quality drinking water, the claimed solution meets the condition of "inventive step".

 Figure 1 presents a longitudinal section of the claimed cartridge; FIG. 2 and FIG. 3 is a longitudinal section through the connection of the lid and the disinfection cartridge.

 Figure 1 shows an example of the best performance of the inventive cartridge.

 The cartridge for disinfecting drinking water consists of a housing 1, to the bottom of which a removable bottom 2 is attached, lids 3 with a fitting 4 and channels 5 intersecting the annular protrusions of the lid 6, a device for supplying water 7 below the bactericidal material 8 located between the two grilles 9a and 9b and layers of carbon fiber material 10a and 10b, a layer of carbon fiber material 10c located under the lower grill 9b, designed to filter mechanical impurities and secured by the shoulder of the divider 11, a device for providing a supply of water, fiber bed cation exchange material 10d, located above the top grating 9a. The fastening of the cover 3 to the housing 1 is provided by annular conical protrusions of the housing 12 and the cover 6, extending one after another. Disinfected water leaves the cartridge through channels 5 intersecting the annular protrusions 12 and 6. Moreover, the step of the protrusions of the cover 6 is greater than the step of the protrusions of the housing 12, which provides the necessary passage section of the channels 5.

 Disinfection of water in the cartridge is as follows.

 Water through the nozzle 4 and the device for supplying water 7 with a water divider 11 enters the removable bottom 2 and through the filter layers of the carbon fiber material 10 with 10b and the grate 9b placed between the layers of the carbon fiber material passes from bottom to top through a layer of bactericidal material 8, where water disinfection occurs, passes through the layers of fiber carbon material 10a and fiber cation exchange material 10d, separated by a lattice 9a, and flows out of the cartridge through channels 5.

 In the presence of mechanical impurities in the source water, they are retained by the layer of fiber carbon material 10c and then settle in the bottom 2.

 The performance of the cartridge was determined by its throughput (resource), the change in the rate of passage of water through the device and the effectiveness of disinfection. The disinfection efficiency and throughput (resource) of the cartridge was determined by the microflora content in a certain amount of water passed through the cartridge. The change in the speed of water passage was determined by the amount of water in ml passing through the cartridge for 1 min at a constant pressure of water throughout the life of the resource. The design of the cartridge ensures the passage of water, already cleared of mechanical impurities that are trapped in the removable bottom, through the layer of bactericidal material from the bottom up. This ensures a more effective contact of water with the bactericidal material and excludes caking and compaction of the bactericidal material, as well as the possibility of mechanical impurities entering it.

 If a polygaloid resin with a particle size distribution of less than 0.2 mm is used, then the fine fraction can be carried away by the flow of water into the possible gaps between the layers of the fiber material.

 When using fractions of more than 1.5 mm, the disinfection efficiency is reduced.

When using fiber carbon material with a weight of less than 400 g / m ² it has a more loose structure and can be destroyed by the flow of water.

 When using fiber cation exchange material having a volumetric capacity of less than 4 mEq / g, the efficiency of water purification is reduced.

 The used ratio of the layers is explained by the fact that with a smaller than the claimed volume ratio of the fiber carbon material, polyhaloid resin and fiber cation exchange material, the disinfection efficiency decreases, and a larger ratio than the claimed entails an increase in the dimensions of the cartridge and a decrease in the rate of water filtration.

 In the inventive cartridge uses a polygaloid anion exchange resin with a particle size distribution of 0.2 - 1.5 mm This particle size distribution complies with the regulatory documentation for the resin.

Example 1. The cartridge for disinfecting water includes the following layers along the water: carbon fiber material with a weight of 400 g / m ² ;
polygaloid anion exchange resin with a particle size distribution of 0.2 - 1.5 mm;
carbon fiber material with a weight of 400 g / m ² ;
fiber cation exchange material with an exchange capacity of 4 mEq / g.

 The volume ratio of the layers is 1.5: 3.5: 0.5: 1.5.

 The initial filtration rate is 1100 ml / min, the final filtration rate is 1000 ml / min, the resource is 5000 l, the results of microbiological studies are shown in the table.

 Example 2. The cartridge for disinfecting water includes the same layers along the water, as in example 1; wherein the ratio of the layers is 1: 4.5: 1: 0.5.

 The initial filtration rate is 1100 ml / min, the final filtration rate is 1050 ml / min, the resource is 5000 l, the results of microbiological studies are shown in the table.

 Example 3. The cartridge for disinfecting water includes the same layers along the water, as in example 1; wherein the ratio of the layers is 1: 3.5: 1: 1.5.

 The initial filtration rate is 1100 ml / min, the final filtration rate is 1000 ml / min, the resource is 5000 l, the results of microbiological studies are shown in the table.

 Based on the results of microbiological studies, we can conclude that the use of a cartridge for water disinfection allows to ensure guaranteed disinfection from bacteria, viruses and bacteriophages almost regardless of the initial contamination of water. The cartridge is characterized by small dimensions, low cost, versatility and high work efficiency.

Claims (5)

 1. A cartridge for disinfecting drinking water, comprising a housing, perforated partitions, layers of carbon fiber and fiber cation exchange material, a bactericidal material, characterized in that in the upper part of the housing there is a lid with a fitting and channels for the passage of disinfected water, and the lid is equipped with a device water supply to the bottom mounted in the housing coaxially or offset from its axis, in addition, the cartridge is equipped with a water divider, which is placed inside the device for both sintering the water supply and has a flange, and the partitions are made in the form of gratings located in the lower and upper parts of the device for providing water supply, the fiber material being located on both sides of the gratings, and the bactericidal material between the gratings, on both sides of which fiber carbon material is placed .  2. The cartridge according to claim 1, characterized in that the bactericidal material is a polygaloid anion-exchange resin with a particle size distribution of 0.2-1.5 mm 3. The cartridge according to claim 1, characterized in that the carbon fiber material is a fiber with a weight of at least 400 g / m ² .  4. The cartridge according to claim 1, characterized in that the fiber cation exchange material has an exchange capacity of at least 4 mEq / g.  5. The cartridge according to claim 1, characterized in that it contains successive layers of fiber carbon material, polygeloid anion exchange resin, fiber carbon material and fiber cation exchange material in the following layer volume ratio: 1.5: 3.5: 0.5: 1.5 - 1.0: 4.5: 1.0: 0.5.

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