RU2181704C2 - Unit for cleaning water and method of its regeneration and decontamination - Google Patents

Abstract

FIELD: units for cleaning tap water; regeneration and decontamination of water cleaning units. SUBSTANCE: proposed unit has housing with bottom and inlet and discharge branch pipes, hose, multi-stage medium containing cation-exchange fibers, activated carbon impregnated with silver and anion-exchange fibers. Multi-stage medium is placed between upper and lower distributing grates; area of upper grate is lesser than that of lower grate by 30 to 40%. Lower distributing grate is supported by splitter plate of bottom. Inlet branch pipe changes to pressure passage which is filled with filamentary prefilter; size of particles entrapped by prefilter is lesser than that of pores of cation-exchange fibers by 15 to 35%. All inner surfaces of units are coated with layer of bactericidal agent. Method of regeneration and decontamination of unit consists in mechanical cleaning of filamentary prefilter by 3.0 - 4.5% aqueous solution of sodium bicarbonate (NaHCO₃) followed by treatment by 1.2- 1.5% aqueous solution of citric acid (C₆H₈O₇).. Regeneration and decontamination of medium is performed by means of 5-8% aqueous solution of sodium bicarbonate (NaHCO₃) mixed with 0.5-1.0% of aqueous solution of hydroperit (H₂O₂) for 10-15 minutes, after which solution is drained and repeated treatment by regenerating solution is carried out which is left in unit for at least 4 hours. EFFECT: enhanced efficiency of preliminary cleaning and final cleaning; possibility of obtaining safe drinking water from microbiological standpoint. 3 cl, 1 dwg, 2 tbl

Description

 The invention relates to a device for cleaning tap water from mechanical impurities and suspended particles, iron, toxic metals, organic and organochlorine substances, active chlorine, nitrates, nitrites, bacteria, eliminating extraneous tastes and odors, is intended for drinking water at home and provides The method of regeneration and disinfection of the device.

 Currently, various designs of water purification devices having multi-stage loading are known [DE N 4032265, DE 3826857, RU 2078046]. As a filter load, as a rule, layers of cation exchange and anion exchange materials, activated carbon, most often impregnated with silver, or a special layer of bactericidal material are used [RU 2078046].

 The regeneration of such devices is also known [DE 3826857] and is due to the filter load placed in the device.

 The closest in technical essence and the achieved result to the proposed device is a device for water treatment, comprising a housing, supply and outlet pipes, flow guiding plates and a multilayer sorption charge, the layers of which are separated from each other by separators with holes. Moreover, the total area of the holes of the upper plate is less than the total area of the holes of the lower plate [RU 2075446].

The closest method of regeneration is proposed in the applications DE 4032265, DE 3826857, the regeneration is carried out using a composition that includes oxides of iron (Fe) and copper (Cu), sodium chloride (NaCl) and salts containing SO ₄ ^2- , CO ₃ ^{2 -} , NSO ₃ ^- .

The main disadvantages of these devices, methods for their regeneration include:
1. The absence or insufficient pretreatment of mechanical impurities and suspended particles, which leads to a deterioration in the work of the main load.

 2. The presence of conditions and factors for the development of microorganisms, incl. and in the filter load.

 3. The absence or insufficient bactericidal treatment of the device itself and the disinfection of multi-stage loading, which also leads to the development of microorganisms.

 4. Inadequately efficient regeneration of multi-stage loading leads to a reduction in the service life of the device and insufficient cleaning efficiency, especially during prolonged use.

 The aim of the invention is to provide an effective pre-treatment, bactericidal treatment of the device and the filter load in the water treatment device, in addition, reliable mechanical cleaning and regeneration of the pre-filter and regeneration with disinfection of the filter load to restore its sorption properties and exclude the development of microorganisms should be provided, including using constructive solutions.

 The problem is achieved due to the fact that in the known device for water purification, comprising a housing, inlet and outlet pipes with a hose, distribution grilles, multi-stage loading, the pressure channel is made in the form of a hollow cylinder resting on the dividing walls of the bottom of the housing, on which the lower distribution grid. A fiber prefilter is placed in the pressure channel of the device, and a multi-stage loading is located in the housing between the upper and lower distribution grids and consists of layers of cation-exchange fiber, activated carbon impregnated with silver, anion-exchange fiber successively located from the bottom upwards along the course of the purified water. In this case, the particle size retained by the prefilter is 15-35% smaller than the pore size of the cation exchange and anion exchange fibers, and the area of the upper distribution lattice is 30-40% of the area of the lower distribution lattice. Moreover, a layer of bactericidal substance in a water-insoluble form is applied to all the inner surfaces of the housing, pipes, hose, pressure channel, and the surface of the distribution grids.

The problem is also solved due to the fact that in the device for water purification, the fiber prefilter is mechanically cleaned with a 3.0-4.5% aqueous solution of baking soda (NaHCO ₃ ), followed by treatment with a 1.2-1.5% an aqueous solution of citric acid (C ₆ H ₈ O ₇ ), and the regeneration and disinfection of multi-stage loading is carried out with a 5-8% solution of soda (NaHCO ₃ ) in a mixture with a 0.5-1.0% aqueous solution of hydroperite (N ₂ O ₂ ) for 10-15 minutes, after which the solution is drained and re-treated with a regenerating solution, followed by exposure to device for at least 4 hours

 The prefilter plays an important role in the operation of a water treatment device, since, by delaying mechanical impurities and suspended particles, it must create optimal conditions for the operation of the main filtering multi-stage loading. In this case, the size of particles retained by the prefilter with respect to the pore size of the fibrous ion-exchange materials is of great importance. If the size of the particles retained by the prefilter is less than the pore size of the ion exchange fiber, then after the prefilter clogs, the device will “jump off” the water tap when it is entering water. And if the size ratio of the detained particles is close, then a breakthrough of mechanical impurities and contamination of the multi-stage loading are possible, which is also unacceptable. If the ratio is too large, then the formation of stagnant zones for water in the device is possible, in addition, the device will often "jump off" from the tap, which creates inconvenience for the user. It has been experimentally determined that the size of particles retained by the prefilter should be 5-20% smaller than the pore size of cation exchange and anion exchange fibers.

 An important condition for effective cleaning of a multi-stage loading is the uniform distribution of the stream of purified water throughout the entire volume of the load. To solve this problem, distribution grids are provided in the device, between which there is a filter load. In addition, to exclude the formation of stagnant zones in the device where microorganisms that have fallen from the source water can develop, the distribution grilles are designed in such a way that the ratio of their diameters and free cross-sectional areas provides the necessary hydrodynamics of the flow of purified water. At the same time, introducing such structural limiting features into the device, one cannot allow the contact time of the water to be treated with the top of the charge to be significantly reduced, in particular, an anion-exchange fiber layer, the dimensions of which correspond to the size of the distribution grid.

 It was experimentally determined that optimal conditions are created when the area of the upper distribution grid (and, accordingly, the diameter and free cross-sectional area) is 30-40% of the lower area.

Cleaning the fiber prefilter from settled mechanical impurities and suspended particles is well carried out in an alkaline environment, therefore, an aqueous solution of baking soda (NaHCO ₃ ) was chosen as the regenerating reagent, and to remove contamination (including colloidal iron), which were sorbed by the highly branched surface of the fibers prefilter, it is necessary to carry out processing in an acidic environment, for example using an aqueous solution of citric acid, which dissolves the remaining colloidal iron and, along with soda partially disinfects prefilter. All reagents are selected from the conditions that the proposed device is intended for use at home and the user should be able to easily purchase reagents for washing and regeneration.

The choice of reagent concentration is determined, on the one hand, by ensuring a sufficient degree of purification and regeneration, and, on the other, by technological and economic feasibility, since an excessive concentration of washing reagents in the solution does not increase the degree of purification of the prefilter. It was experimentally determined that the optimal concentrations are 3.0-4.5% aqueous solution of baking soda (NaHCO ₃ ) and 1.2-1.5% aqueous solution of citric acid (C ₆ H ₈ O ₇ ).

Organic substances absorbed by activated carbon are desorbed from its micro- and macro-surfaces when they are converted into a dissociated form when the pH changes by 3-4 units. It is known that baking soda (NaHCO ₃ ) is a fairly effective means for the regeneration of activated carbon from organic pollution, as it has an alkaline character. During regeneration with an alkaline soda solution, organic electrolytes are converted into a dissociated form with their transition from pores of coal to the volume of the solution.

It has been experimentally proved that the total effectiveness of using a mixture of baking soda and hydroperite (NaHCO ₃ and H ₂ O ₂ ) as a regenerating solution is much higher, because H ₂ O ₂ , in addition to disinfection, also oxidizes organic compounds on carbon to the simplest compounds, which helps to restore the adsorption properties of activated carbon. In addition, soda (NaHCO ₃ ) in the form of Na ⁺ and HCO ₃ ^- ions serves to regenerate cation exchange and anion exchange fibers. The choice of the concentration of NaHCO ₃ and H ₂ O ₂ solutions is based on the need for complete regeneration and disinfection of multi-stage loading. Small concentrations will not ensure the completeness of the process, the use of solutions of high concentrations of reagents is also impractical due to the excessive costs of the reagents. The processing time of a multi-stage loading with a regenerating solution and the sequence of operations are primarily determined by the nature of the contaminants and the rate of diffusion of the contaminants into the regenerating solution from the pore volume of the coal.

 It has been experimentally proved that the primary processing of multi-stage loading should be carried out for at least 10-15 minutes, during which the limiting diffusion of organic pollutants into the solution and their oxidation on the surface of the coal takes place. To achieve a higher degree of regeneration with the completion of all the processes accompanying it, a secondary treatment with a regenerating solution is carried out with the solution kept in the device for at least 4 hours.

 The main parameters and test results of the claimed invention are presented in table. 1 and 2.

 The invention is illustrated in the drawing.

 A device for water purification consists of a housing 1 and a bottom screwed onto it 2. On the inner surface of the bottom 2 there are dividing partitions 9. The device has an inlet pipe 3, a discharge pipe 4, on which a hose 5 is put on to drain purified water. In the inlet pipe there is a rubber seal 14 fixed by a sleeve 16, which serves to fasten the device to the water tap. The inlet pipe 3 passes into a cylindrical pressure channel 8, which is filled with a fiber prefilter 10. The lower distribution grid 7 rests on the partition walls 9 of the bottom 2, on which a cation exchange fiber 11 is laid, then activated carbon 12 impregnated with silver. An anion-exchange fiber 13 is placed on the surface of the coal, which is closed by the upper distribution grid 6. On all internal surfaces of the housing 1, bottom 2, nozzles 3 and 4, hose 5, pressure channel 8, distribution grids 6 and 7, a layer of bactericidal substance 15 is applied in a water-insoluble form .

 A device for water purification works as follows.

 The device using the sealing ring 14 located in the inlet pipe 3, put on the spout of the water tap, turn on cold water and set the flow rate of not more than 8-12 l / hour. This flow rate is due to the necessary contact time of the source water with the prefilter 10 and multi-stage loading to ensure the completeness of the cleaning process.

 The source water enters the pressure channel 8 and contacts the fiber prefilter 10, on which mechanical particles, suspensions, colloidal iron are retained, thereby improving a number of indicators of water quality (turbidity, color, iron). Then, the flow of source water with the help of partition walls 9 of the bottom 2, and then the lower 7 and upper 6 distribution grids is evenly distributed over the entire volume of the multi-stage loading. Once in the layer of cation exchange fiber 11, the source water is purified from toxic metals (copper, zinc, aluminum, lead, etc.), hardness salts (partially from Ca and Mg), ferrous iron.

 Activated carbon 12, impregnated with silver, helps to remove organic impurities from water, including organochlorine, active chlorine, heavy metals, which helps to reduce the color of the water, remove the smell and taste of water. In addition, silver ions contained in activated carbon 12, have a disinfecting effect on the treated water and protect the device from microflora overgrowth, inhibiting its development. The last of the layers of multi-stage loading - anion exchange fiber 6, removes nitrates, nitrites, phosphates, sulfates, and other anions from water. After that, water through the outlet pipe 4 and the hose 5 is supplied to the consumer. A layer of bactericidal substance 15, deposited on all internal surfaces of the device, additionally provides microbiologically safe drinking water and serves to protect the device from secondary biodefeat in between the operation of the device.

Literature
1. The filter for water purification, RU 207846, MKI ⁶ C 02 F 1/18.

2. Filter system for drinking water, DE 3826857, MKI ⁵ C 02 F 1/00.

3. Installation for filtering drinking water, DE 4032265, MKI ⁵ 02 F 1/00, B 01 D 29/62.

4. Device for water treatment, RU 2075446, MKI ⁶ C 02 F 1/28 - prototype.

Claims (2)

 1. A device for water purification, comprising a housing with a bottom, an inlet pipe, a discharge pipe with a hose, distribution grids, multi-stage loading, characterized in that the pressure channel is made in the form of a cylinder resting on the partition walls of the bottom of the housing, on which the lower distribution grid is placed , a fiber prefilter is placed in the pressure channel of the device, a multi-stage loading is located in the housing between the upper and lower distribution grids and consists of sequentially located x from bottom to top in the direction of the purified water of the layers of cation-exchange fiber, activated carbon impregnated with silver, anion-exchange fiber, while the size of particles retained by the prefilter is 15-35% smaller than the pore size of the ion-exchange fiber, the area of the upper distribution lattice is 30-40% of the area, respectively lower distribution grid, and on all internal surfaces of the housing, nozzles, hose, pressure channel, on the surface of the distribution grilles, a layer of bactericidal substance in a water carrier is applied soluble form. 2. The method of regeneration and disinfection of the device according to claim 1, characterized in that the fiber pre-filter is mechanically cleaned with a 3.0-4.5% aqueous solution of baking soda (NaHCO ₃ ), followed by a treatment of 1.2-1.5 % aqueous solution of citric acid (C ₆ H ₈ O ₇ ), and the regeneration and disinfection of multi-stage loading is carried out with a 5-8% aqueous solution of baking soda (NaHCO ₃ ) in a mixture with 0.5-1.0% aqueous gidroperita (H ₂ O ₂₎ for 10-15 min, after which the solution was emptied and re-processing is performed regenerant solution followed by aging in the apparatus for at least 4 hours.

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