RU2083500C1 - Method and apparatus for sorption treatment of water - Google Patents

Abstract

FIELD: water treatment. SUBSTANCE: method can be used for treating drinking water in home conditions and at food industry enterprises and allows system purification of water from inorganic and organic impurities and toxic substances as well as from microorganisms. Method includes passing water successively through beds of coal material with rate 10-50 specific volumes per hour in respect to volume of coal material beds exposed to electric potential at direct current voltage 3-12 v. Apparatus has casing with a partition separating casing into preliminary treatment and treatment chambers, two coal material beds (granulated activated carbon), diaphragms, and direct current source. EFFECT: increased purification degree. 2 cl, 3 dwg, 4 tbl

Description

 The invention relates to water treatment, namely to the purification of drinking water, and can be used for local treatment of tap water in domestic conditions, at food industry enterprises, child care facilities and healthcare enterprises. The invention can also be used at industrial water treatment plants.

 A known method of water purification, including passing the latter through activated carbon [1] This method allows you to partially remove dissolved organic impurities, chlorine, microorganisms from water by sorption on activated carbon. The main disadvantages of this method are the low degree of purification of water from dissolved natural organic substances, especially humic and fulvic acids, the impossibility of this method of purifying water from toxic inorganic impurities of an ionic nature, the possibility of overgrowth of the sorbent layer by toxic microorganisms during operation.

 A device for water purification is known, which is a container filled with activated carbon, as well as nozzles for water inlet and outlet [1] However, this device is ineffective, since it does not provide a long-time protective effect of the sorbent.

 Closest to the proposed method in terms of technical nature and the achieved result is a method in which water is passed sequentially through layers of carbon material [2] Granulated activated carbon is used as the first layer, and microporous carbon fabric as the second. The method allows to achieve a high degree of purification of water from organic impurities, but does not provide a comprehensive purification of water at the same time from inorganic, organic and biological impurities.

 The closest technical solution to the invention is a device for sorption water treatment, comprising a housing with two layers of coal material and water inlet and outlet pipes / 2 /. In this device, an internal element (first layer) of granular activated carbon and an external element (second layer) of microporous carbon fabric are placed in the device case. The purified water passes through the perforated channel, the internal and external elements of the device and is discharged from the housing through the pipe. The disadvantages of the known device are the ability to quickly calcify microporous tissue, the need to disassemble the device to remove mechanical impurities, the need to use special devices to achieve tightness. The main disadvantage of the device is the inability to carry out a comprehensive water treatment on it.

 The tasks to be solved are for the method of providing comprehensive water purification from polluting and toxic impurities of inorganic and organic substances, as well as microorganisms, for the device creating a device that allows complex water purification that does not require additional devices to achieve tightness, and having the ability to periodically remove mechanical impurities for account for the return of water.

 The problem is solved in that in the method of sorption purification of water by passing the latter sequentially through layers of coal material, water is passed at a rate of 10-50 specific volumes per 1 h relative to the volume of layers of coal material under electric potential at a DC voltage of 3 12 IN.

 The problem is solved in that in a device for sorption water treatment, including a housing with two layers of coal material and with water inlet and outlet pipes, the device is equipped with a partition installed in the housing and dividing it into interconnected pre-treatment and cleaning chambers, filled respectively with the first and the second layers of carbon material, diaphragms of a dielectric material and a constant current source, the side walls of the chambers are made of electrically conductive material and connected to a source of With a constant current, the diaphragms are located between the walls of the chambers under the anode potential and the layers of coal material under the cathode potential and are made in the pre-treatment chamber from a material with hydrodynamic resistance lower than the resistance of the first layer, and in the cleaning chamber from a material with hydrodynamic resistance greater than the resistance of the second layer, the nozzles are located on the opposite side of the chamber connection, and the water inlet pipe is located in the pre-treatment chamber, and the pipe Displayed cleaning water located in the chamber, the carbon layers as the filling material is granular activated carbon.

 In FIG. 1 shows a General view of the device, section; figure 2 view aa in fig. one; figure 3 view BB in fig. one.

The novelty of the proposed method and device is associated with the use of activated carbon simultaneously as a volume electrode and a sorbent, due to the ongoing electrochemical processes on the surface of which an effective integrated water treatment is provided. The essence of the ongoing processes can be described as follows. Typical drinking water pollution can be divided into 4 classes:
inorganic substances, heavy metal cations (lead, copper, mercury, cadmium, etc.), non-ferrous metal cations (chromium, nickel, cobalt, zinc, etc.), excessive amounts of iron and its compounds in dissolved and undissolved forms, chlorine, sulfur-containing compounds, nitrates, borates;
natural organic substances, mainly humic and fulvic acids and their derivatives;
industrial organic substances, phenols, organochlorine formed in industrial water treatment systems, toxic organic substances used in agricultural chemistry, in the manufacture of dyes, etc.

 biologically active substances, microbes and bacteria (most often, E. coli), etc.

 In the process of passing water through an electrically polarized layer of activated carbon and in the course of electrochemical reactions with the formation of atomic oxygen, the destruction of complex compounds of humic and fulvic acids and the precipitation of decomposition products in the sorbent phase occur. Chlorine, nitrate and borate anions and oxychloro compounds are absorbed and also reduced, for example, to the chloride anion and nitrogen in the cathodic process. Organic substances (phenols, organochlorine compounds) are physically sorbed in highly porous material. Microorganisms are destroyed by the anode process at potentials corresponding to the oxygen discharge, and the decomposition products are adsorbed by coal. In this process, atomic oxygen is restored, and pure water is saturated with molecular oxygen, due to which, simultaneously with water purification, it is conditioned and organoleptic properties improve.

 The proposed method and device provide comprehensive purification and conditioning of water without changing the micro and macro composition required for drinking water by using activated carbon simultaneously as a sorbent and bulk electrode and due to the special design of the device and the process conditions.

 The authors are not aware of any other methods and devices providing a comprehensive purification of drinking water using only activated carbon as sorbents.

 When implementing the method, it is advisable to maintain the voltage on the electro-absorber within 3-12 V. When the voltage decreases, the efficiency of the cleaning process decreases, when the potential on the coal layer exceeds 12 V, the service life of the volume electrode decreases with constant efficiency. The optimal voltage depends on the properties of the source recycled water and can be selected according to the results of water analysis under various conditions within the specified voltage range.

It is advisable to maintain the speed of transmission of water through the layers of coal material in the range of 10-50 specific volumes per 1 h in relation to the total volume of the layers of coal material. A decrease in speed of less than 10 h ^-1 does not increase the cleaning depth at lower productivity, an increase in speed above 50 h ^-1 leads to a decrease in the cleaning depth and a decrease in the time of the protective action of a single loading of the sorbent. The optimal speed (within the specified range) depends on the properties of the source recyclable water and can be selected experimentally.

 Subject to optimal conditions, the capacity of the layers of coal material in the electrosorption process when the effectiveness of integrated water treatment can be achieved can be maintained for one year or more.

 Example 1. Through the device shown in figure 1, when filling 200 ml of activated carbon SKN brand with a grain size of 20 to 100 microns for 3 days, recycled water is continuously passed at a speed of 5 l / h at a voltage of 9 V. water was taken from a well used for drinking purposes in one of the children's health-improving institutions of Zelenogorsk, Leningrad Region. The current strength in the external circuit at a voltage of 9 V is 60 mA. Tables 1 and 2 show the results of analyzes of the source and treated water after the process reaches the stationary mode (which is controlled by preliminary analyzes). As can be seen from the tables, during the processing, the concentration of total humus is reduced 100 times, the iron content in purified water is in compliance with the standards, E. coli and hydrogen sulfide are completely removed, the water from slightly alkaline becomes neutral, partial softening occurs while maintaining the overall balance of macrocomponents.

 After the process is carried out continuously for 10 days, the operation of regeneration and purification of the layers of coal material from mechanical impurities is performed by supplying water in the opposite direction at a speed of 10 l / h for 15 min when the electrical potentials are reversed. The device is brought to its initial state and the process of water purification is continued with obtaining purified water of the composition shown in Tables 1 and 2.

 Example 2. The process is carried out as in example 1, except that the tap water of St. Petersburg is passed through the electric adsorber. The transmission rate of water is 8 l / h, the voltage at the electric absorber is 6 V, and the current strength is 40 mA. Tables 3 and 4 show the results of analyzes of the source and purified water after the process reaches the stationary mode. As can be seen from the tables, the content of toxic metals is significantly reduced, dissolved chlorine is completely removed, humus, nitrate and borate ions are almost completely removed. Partial softening of water occurs while maintaining the overall balance of macrocomponents, the pH of the water, as in example 1, becomes equal to 7.4, which is most optimal for drinking water of the bicarbonate type.

 The device shown in figures 1-3, consists of a housing in the form of a flat parallelepiped. The housing has a frame 1 of a dielectric material, for example, Teflon or polyethylene, and side walls 2 and 3 made of an electrically conductive material, for example titanium. The housing is equipped with a partition 4, dividing it into interconnected pre-treatment and cleaning chambers. The chambers are filled respectively with the first 5 and second 6 layers of carbon material, which is used as a backfill of granular activated carbon. The housing is equipped with nozzles for input 7 and output 8 of water. The nozzles 7 and 8 are located on the opposite side of the connection of the chambers, while the inlet nozzles 7 are located in the pre-treatment chamber, and the outlet pipe 8 is located in the cleaning chamber.

 The device is equipped with a direct current source (not shown) connected to the side walls of the chambers 2 and 3, and diaphragms 9 and 10 of dielectric material located between the first side wall 3 of the casing under the anode potential and the layers 5 and 6 under the cathode potential (due to the connection of the second side wall 2 of the housing to the negative pole of the DC source). The diaphragms 9 and 10, respectively, are made in the pre-treatment chamber from a material with a hydrodynamic resistance less than the resistance of the first layer 5, and in the cleaning chamber from a material with a hydrodynamic resistance greater than the resistance of the second layer 6.

 The invention is illustrated in table. 1-4.

 The device operates as follows. The processed source water is supplied through the input pipe 7 sequentially to the pre-treatment chamber, and then into the purification chamber and through the output pipe 8 leaves in the form of purified and conditioned water. Moreover, because of the smaller hydrodynamic resistance of the diaphragm 9 than that of the layer 5, water mainly flows through the anode space in the pre-treatment chamber (between the side wall and the diaphragm), and because of the greater diaphragm hydrodynamic resistance of the coal layer 6 than the coal layer 6 10, water mainly flows through the cathode space (through a layer of coal 6, which is electrosorbent). The main electrooxidative processes occur in the anode space (pre-preparation chamber), including the formation of atomic hydrogen, the destruction of complexes of humus with heavy metals, the partial destruction of bicarbonate complexes, the partial formation and sorption of metal hydroxides, and the destruction of microorganisms. In the cathode space (purification chamber), reductive destruction and sorption of toxic anions, absorption of chlorine and organochlorine, phenols, complete absorption of residues of oxidative destruction of toxic substances in the pre-treatment chamber, molecular oxygen formation and water saturation take place.

 The proposed method and device through the use of special conditions of the process and a special design provide integrated purification of drinking water. The additional costs in this case compared to conventional methods and devices using activated carbon are disproportionately small in comparison with the achieved effect. In particular, the consumed electric power for a device with a capacity of 10 l / h. which can be used in domestic conditions, does not exceed 1 W.

Claims (2)

 1. A method of sorption treatment of water, comprising sequentially passing water through two layers of coal material, characterized in that the water is passed at a rate of 10 50 specific volumes per hour relative to the volume of layers of coal material under the cathode potential at a DC voltage of 3 12 V, and as layers of coal material, granular activated carbon backfill is used.  2. A device for sorption water purification, comprising a housing with two layers of coal material, water inlet and outlet pipes, characterized in that it is additionally equipped with a partition installed in the housing and dividing it into interconnected pre-treatment and cleaning chambers, filled respectively with the first and the second layers of carbon material, diaphragms made of dielectric material, and a constant current source, the diaphragms are located between the walls of the chambers made of electrically conductive material a and connected to the positive pole of the current source, and layers of coal material connected to the negative pole of the current source, and are made in the pre-treatment chamber of a material with a hydrodynamic resistance less than the resistance of the first layer, and in the cleaning chamber of a material with a hydrodynamic resistance greater than the resistance of the second layer, water inlet and outlet pipes are located on opposite walls of the housing, while the water inlet pipe is located in the pre-treatment chamber, and the water outlet pipe in the cleaning chamber, the layers of coal material are made in the form of filling granular activated carbon.

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