RU2043308C1 - Method for electrochemical purification of drinkable water - Google Patents

Abstract

FIELD: water electrochemical purification. SUBSTANCE: method consists in that drinkable water, mainly, tap water, is treated with a package of parallel soluble electrodes under nonrunning conditions. After disconnection of electrodes, water is mixed with current conducting grounded object and filtering is effected after formation of large coagulant floculents sizing 1.5- 2.5 mm. EFFECT: higher efficiency. 1 dwg, 1 tbl

Description

 The invention relates to electrochemical technology for water treatment and can be used in domestic conditions to improve the consumer properties of drinking water, mainly tap water.

 Currently, methods based on water filtration are widely used for the purification of tap water. Known methods for treating tap water by passing it through successive filter systems: primary (to remove large particles), a carbon filter, an ion exchange resin and an ultrafilter membrane (UK Application N 2197860, CL 02 F 9/00, 1988), as well as passing tap water in a domestic water supply system through an ion-exchange resin and a mixture of dolomite and coal (UK Application N 2198432, CL 02 02/42, 1988).

 A disadvantage of the known methods based on sequential filtration of water is the deterioration of its biological properties due to demineralization when passing through an ion-exchange resin, as well as the need for periodic replacement of filters, in particular for regeneration of an ion-exchange resin, which complicates the use of known methods in domestic conditions and makes their more expensive.

 There is a method of purifying drinking water by passing it through a filter and an electrolytic disinfecting cell, with which the chlorides contained in the water partially react with the formation of hypochlorite (German Application Laid-Open No. 3714200, class 02 F 1/46, 1988).

 The disadvantage of this method is its narrow specificity in electrochemical processing (only disinfection of water), without improving other consumer properties of water (deodorization, discoloration, lightening).

 There is a method of electrotreating small quantities of liquids from impurities by passing it through coagulated and polarized chain aggregates formed of solid particles at such a speed that the fluid flow forces are less than or equal to the electric forces holding the aggregates on the electrodes (USSR Author's Certificate N 333132, class . 02 B 1/82, 1972).

 A disadvantage of the known method of electric purification of liquids is the difficulty of its implementation, which consists in the need for accurate observance of the fluid flow rate adequate to the voltage at the electrodes and the distance between them, which complicates its use in domestic conditions for the purification of drinking water.

 The closest set of features to the claimed method is a method of electrochemical treatment of water by treating it with a packet of soluble aluminum electrodes with periodic polarity changes simultaneously in flowing and non-flowing modes. To do this, the interelectrode spaces are blocked through one to create a non-flow regime of liquid purification. When changing the polarity of the electrodes, previously opened interelectrode spaces are blocked. Thus, in each pair of adjacent interelectrode spaces, water is electrically cleaned simultaneously in flowing and non-flowing modes (USSR Author's Certificate N 1165639, class C 02 F 1/46, 1985).

 The known method of electrochemical water treatment, despite a number of advantages (reducing energy consumption for cleaning and increasing the degree of purification by creating a non-flow mode), has the following disadvantages. Firstly, using the known method it is impossible to achieve the maximum degree of water purification and improve its consumer properties, since the presence of a flow regime helps to reduce these characteristics. This is explained by the fact that in flowing modes of water treatment there is a constant supply to the anode and deposition of hardness salts on it, which prevent dissolution of the anode and thereby reduce the degree of water purification in open interelectrode spaces, which reduces the degree of water purification in general and does not allow maximum improve consumer properties of water. Secondly, the known method is quite complicated in practical implementation when creating simultaneously flowing and non-flowing modes in each pair of adjacent interelectrode spaces, as well as providing a change in modes (flowing to non-flowing) when switching the polarity of the electrodes. Thus, the use of the known method of electric water purification in domestic conditions is of great difficulty and does not allow to obtain the desired result to improve the consumer properties of drinking water and the degree of its purification.

 The invention is aimed at solving the following problem: to create a simple, convenient for use in domestic conditions, method of additional purification of drinking, mainly tap water, to maximize its consumer properties and reduce the amount of harmful impurities contained in it. The relevance of the task due to the fact that at present, due to a sharp deterioration in the environmental situation, the water of any water supply does not meet the established criteria and the health and life of the population of the cities depend on the solution of the task.

When solving this problem, a significant improvement in the consumer properties of tap water is achieved, and such an important indicator, which is not included in GOST 2874-82 "Drinking water", as oxidizability. This indicator is integral with respect to organic impurities located in water, and, determining the oxidizability, they determine the degree of its contamination. The hygienic standard that determines how much oxygen is needed to oxidize the impurities contained in water, for pure waters, the value of permanganate oxidizability equal to 6 mg O ₂ / l.

 The technical result of the proposed method for the electrochemical treatment of drinking water (improving the consumer properties of water and simplifying the method) is achieved by treating the water, mainly tap water, in a non-continuous mode with a packet of parallel soluble electrodes at an energy consumption of 1000-1200 J / l of water, after disconnecting the electrodes, the water is mixed a conductive object, and filtering is carried out after the formation of large flakes of coagulant.

 Distinctive features from the prototype are the processing of drinking water in a non-continuous mode at an energy consumption of 1000-1200 J / l of water, mixing immediately after disconnecting the electrodes with a conductive object and filtering the water after the formation of large flakes of coagulant. Since in the process of searching for sources of information and analysis of known solutions the applicant did not find an analogue characterized by features identical to all the essential features of the invention, the claimed method of electrochemical treatment of drinking water meets the requirement of novelty.

 The method of electrochemical water purification by treating it with a package of parallel soluble electrodes (electrocoagulation method) is widely used for the treatment of wastewater, industrial, natural waters, including drinking water (for example, USSR copyright certificate N 1293113, class 02 F 1/46, 1987). At the same time, various technical results are achieved: an increase in the degree of water purification from impurities, suspended particles, water disinfection, improvement of its chemical properties, etc. Water treatment is carried out mainly in flow mode, the disadvantages of which were considered in the criticism section of the prototype. Water treatment in a non-flow mode (static conditions) allows all types of electrocoagulation processes to be carried out in one volume: polarization, electrochemical, hydrodynamic and concentration coagulation.

 In ordinary (flow-through) reactors, for the implementation of polarization coagulation, it is necessary to create conditions for a low flow rate of the treated water, since otherwise chain aggregates are unstable. In the inventive method, the conditions for polarization coagulation are optimal. Ideal conditions are created for electrochemical coagulation in a non-flow mode, since there is a very weak flow between the electrodes due to gas generation, mixing water in the first stage of processing. Electrolytic coagulation proceeds depending on the current and in the case of the proposed method also goes under ideal conditions. Hydrodynamic coagulation is assigned to the final stage of water purification and, due to vigorous stirring of water by a conductive object after disconnecting the electrodes, proceeds together with concentration coagulation at the coagulant maturation stage, which contributes to the aggregation of aggregates to 1.5-2.5 mm. Since all processes occur under the so-called overvoltage, the resulting near-electrode gases not only create a fluid flow in the volume, but also after disconnecting the electrodes and mixing with a conductive object, facilitate the transport of aggregates to the surface and their compaction. Thus, non-continuous water treatment ensures the creation of conditions under which the desired result is achieved: improving the consumer properties of drinking water and increasing the degree of its purification.

 Energy costs for drinking water treatment in the range of 1000-1200 J / l have been established experimentally and for tap water the optimal value of energy costs is 1100 J / l. It was with this value that the maximum improvement in the consumer properties of tap water and the degree of its purification were achieved. When energy consumption is less than 1000 J / l, the process runs more slowly, the amount of hydroxides of iron and aluminum is significantly reduced, and to achieve the desired result, it is necessary to increase the time of water treatment. With an increase in energy consumption of more than 1200 J / l, the aluminum yield increases with a violation of the maximum permissible concentration (0.25 mg / l), and the process of water purification becomes more difficult due to the large number of gas bubbles deposited on the electrodes. The table shows the results of studies of purified tap water, obtained with an optimal value of energy consumption of 1100 J / l.

 Mixing as a technique is widely used in all reactors where an increase in the number of collisions and acceleration of any reaction is required. The difference of the proposed method is the mixing of a conductive object of the treated volume of water after disconnecting the electrodes. In addition to accelerating the process (the expected result), coagulant particles are significantly and rapidly enlarged, probably due to partial removal of the electric charge from the micelles and their active coalescence. Due to vigorous stirring by a conductive object, hydrodynamic and concentration coagulation begins to occur actively, which contributes to the aggregation of aggregates up to 1.5-2.5 mm. Since all processes in a non-continuous mode proceed under the so-called overvoltage, the generated near-electrode gases not only create a fluid flow in the volume, but also at the end of the electric treatment process (after disconnecting the electrodes and mixing) facilitate transport of the aggregates to the surface and their compaction. The consequence of the flotation process occurring in a non-flowing volume, that is, under ideal conditions, is the rapid clarification of the treated water. However, to simplify the method, filtering can begin, without waiting for the final rise of the sludge to the surface of the treated volume, and spend it at the stage of formation of large flakes of coagulant. This reduces the requirements for filter materials, which can be used as fabrics made from natural fibers with a mesh size of not more than 60 microns (calico, flannel) or cermet porous materials. As the tests showed, filtering water at this stage (the formation of large flakes of coagulant) provides water with high consumer properties and a significantly reduced oxidation value.

 Thus, all of the above allows us to conclude that the entire set of essential features provides the necessary technical result that satisfies the existing public need for purification of tap water. Known attempts to obtain the result were not so successful. According to the applicants, the proposed method corresponds to an inventive step, despite the apparent simplicity.

 The drawing shows a diagram of a device for implementing the inventive method of purification of drinking water.

61 c.A device for treating drinking water consists of a container 1 of a dielectric (for example, a one-, two- or three-liter can) and a cover 2 of insulating material with a package of soluble electrodes 3 and 4 fixed in it in the form of parallel plates. The electrodes 3 are made of an aluminum alloy (for example, AMG-2, AMG-2M), and the electrodes 4 are made of an iron alloy (carbon structural steel ST-3). The electrodes are connected in pairs electrically ("iron" with "aluminum"). A step-down transformer 5, a rectifier 6 and a switch 7 form a power supply for alternately supplying unipolar voltage to the electrodes 3 and 4. The ratio of the active areas of the aluminum to iron electrodes should be in the range 4: 1-6: 1. The dimensions of the electrodes are determined on the basis that they are intended for use with containers with volumes of 1-3 l, which is very convenient in domestic conditions. The processing time of 1 liter of water was determined on the basis of data known in the literature: a safe voltage of 36 V, the optimal current per unit active surface of the electrodes is 0.004 A / cm ² . The active area of aluminum electrodes for the indicated volumes of water (1-3 l) is 124 cm ² (6.2 x 10 x ² ). The power consumption of the device is P = 36x0.004x124 = 18 W (J / s). The processing time of 1 liter of water at an optimal energy consumption of 1100 J / l is
T

61 c.

 PRI me R. Tap water was poured into a 1-liter capacity of 3 liters (a standard three-liter glass jar). After placing the package of electrodes 3, 4 in the water tank, the power supply was turned on. Treatment with 3 L of water was carried out for 3-4 minutes. After that, the power supply was turned off and after removing the lid with a package of electrodes, the water in the jar was actively mixed with a metal spoon (a conductive object). The ripening process of large flakes of coagulant lasts 10-15 minutes with simultaneous flotation to the neck of the jar of mass of waste formed. The floated mass was drained from the neck of the can, and the rest of the water was filtered into a clean container through a funnel with three filter elements embedded in it, for example, calico. At the end of the operation, the filter elements were washed from waste under the tap. It is recommended to store them in a solution of citric acid (1 hour spoon per liter of water). After 20-30 treatments, the electrodes were cleaned of salt deposits with sandpaper or a sharp-edged object. The results of the purification of tap water according to the claimed method are presented in the table.

 The table shows that the consumer properties of tap water improve and become the same in all respects, in addition, it significantly reduces the content of heavy metals, phenols and microorganisms. The inventive method allows in domestic conditions to quickly, easily and efficiently clean small volumes of tap water with minimal energy consumption.

Claims (1)

 METHOD OF ELECTROCHEMICAL CLEANING OF DRINKING WATER, including its processing using a package of parallel soluble electrodes with subsequent filtration, characterized in that the processing is carried out in a non-flow mode, after disconnecting the electrodes, the water is mixed with a conductive object that is grounded, and filtering is carried out after formation of coagulant flakes of size 1, 5-2.5 mm.

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