RU176546U1 - DEVICE FOR ELECTROCHEMICAL WATER TREATMENT - Google Patents

Abstract

Scope: The utility model relates to the field of applied electrochemistry, in particular, to devices for the electrochemical treatment of fresh water to improve its quality, and can be used both in domestic conditions and in public facilities. The essence of the utility model: the device contains a diaphragm electrochemical reactor made of 1-2 vertical cylindrical electrochemical cells, each of which contains electrodes, the interelectrode space of which is divided by a finely porous diaphragm into the anode and cathode chambers with entrances in the upper part of the cells and exits in their lower part, a line for supplying the treated water with a filter installed on it, connected to the input of the anode chamber, an overflow line connecting the output of the anode chamber to the input of the cathode chamber, e a bone with a catalyst, with an entrance at the top and an exit at the bottom, installed on the overflow line, a treated water drain line connected to the output of the cathode chamber, and an additional tank with an entrance at the bottom and an exit of the upper part, using granular activated catalyst coal, an additional tank is installed on the water supply line between the filter and the entrance to the anode chamber, and the additional tank is filled with food-grade granular ion-exchange Na-cation exchange resin. As a catalyst, granular activated carbon from coconut shell with the addition of silver can be used, and layers of nonwoven propylene with a thickness of 5 μm can be used as a filter. 3 s.p. f-ly, 1 il.

Description

The utility model relates to the field of applied electrochemistry, in particular to devices for the electrochemical treatment of fresh water to improve its quality, and can be used both in domestic conditions and in public facilities.

In applied electrochemistry, electrochemical devices of various designs are known for treating and conditioning water. It is known, for example, a device for cleaning, disinfecting and conditioning drinking water, containing a primary and secondary diaphragm electrochemical reactors, the electrodes of each of which are separated by a finely porous diaphragm into an anode and cathode chambers with inputs and outputs, a flotation reactor for separating the gas and liquid phases of the treated source water with an entrance in the middle part and exits in the upper and lower parts, a catalytic reactor with an entrance in the upper and an exit in the lower parts, the feed line for the initial drinking water s, the outlet line for treated drinking water, and the main and additional electrochemical reactors are designed to provide a countercurrent of the treated water in the anode and cathode chambers, the feed line for the source of drinking water is connected to the input of the anode chamber of the main reactor, the output of the anode chamber of the main reactor is connected to the input of the anode chamber additional reactor, the output of the anode chamber of the additional reactor is connected to the input of the flotation reactor, the lower output of the flotation reactor is connected to the input of the catalytic reactor, the output of the catalytic reactor is connected to the input of the cathode chamber of the additional reactor, the outlet line of the treated drinking water is connected to the output of the cathode chamber of the additional reactor (see RF patent No. 2322394, С02F 1/46, 2006). This device allows to increase the degree of purification of water from microorganisms. A disadvantage of the known solution is its comparative complexity, the use of two electrochemical reactors and extended connecting hydraulic lines, which increases the cost of water treatment.

The closest in technical essence is a device for electrochemical water treatment, containing a diaphragm electrochemical reactor made of at least one vertical cylindrical electrochemical cell containing coaxial cylindrical and rod electrodes made of materials insoluble during electrolysis and installed in dielectric bushings, interelectrode space between which it is divided by a ceramic diaphragm into the anode and cathode chambers with inputs at the bottom cells and exits in their upper part, a supply line of treated water with a filter installed on it, connected to the input of the anode chamber, an overflow line connecting the output of the anode chamber with the input of the cathode chamber, a container with a catalyst, with an entrance at the top and an exit at the bottom, installed on the overflow line, the treated water drainage line connected to the output of the cathode chamber, and an additional capacity with an entrance at the bottom and an exit of the upper part (see RF patent for utility model No. 3600, С02F 1/46, 1997). The known solution is quite simple to operate, provides a high degree of purification from microorganisms. However, when using the known solution, the hardness salts present in the reinforcement are converted into an insoluble form and are not removed from the treated water, which reduces the quality of the treatment.

The technical result of using this utility model is to improve the quality of treated water.

This result is achieved by the fact that the device for electrochemical treatment of water contains a diaphragm electrochemical reactor made of at least one vertical cylindrical electrochemical cell, in which electrodes are installed, the interelectrode space of which is divided by a finely porous diaphragm into the anode and cathode chambers with entrances in the upper part of the cells and outlets at their bottom. The device also contains a supply line of treated water with a filter installed on it, connected to the input of the anode chamber, an overflow line connecting the output of the anode chamber to the input of the cathode chamber, a container with a catalyst, with an entrance at the top and an outlet at the bottom, installed on the overflow line, a treated water drain line connected to the output of the cathode chamber, and an additional container with an entrance at the bottom and an exit at the top. Granulated activated carbon is used as a catalyst in the device, an additional tank is installed on the water supply line between the filter and the entrance to the anode chamber and is filled with food-grade granular ion-exchange Na-cation exchange resin.

As a catalyst, granular activated carbon from coconut shell with the addition of silver can be used.

It is advisable to use 5 μm layers of nonwoven propylene as the filter material in the filter.

In addition, a flow sensor can be placed on the overflow line, which is installed between the additional tank and the entrance to the anode chamber.

A device for electrochemical treatment of water contains a diaphragm electrochemical reactor made according to the modular principle and may contain one or two vertical cylindrical electrochemical cells, each of which contains electrodes in which the interelectrode space is divided by a finely porous diaphragm into the anode and cathode chambers with entrances in the upper part of the cells and outlets at their bottom. The implementation of the reactor on a modular basis allows you to easily adjust the performance of the device using one or two cells, depending on the conditions of the task.

The supply line of the treated water with a filter installed on it is connected to the input of the anode chamber, and the output of the anode chamber is connected by a flow line to the input of the cathode chamber. The presence of a filter allows you to clean the supplied water from suspended impurities, prevent their deposition on the surface of the electrodes and reduce the risk of clogging of hydraulic lines, which affects the quality of the treated water. The organization of the flow of treated water sequentially through the anode and cathode chambers improves the quality of cleaning, since it allows, first of all, the oxidation of organic impurities and the disinfection of water in the anode chamber due to the formation of oxidizing agents from salts dissolved in water, such as chlorides, in the anode chamber. After leaving the anode chamber, the treated water enters a container with a catalyst - activated carbon, which is both a catalyst and a sorbent and on which the residual active chlorine is destroyed and sorbed by oxidized organic impurities. Processing water in a chamber with a flow direction from top to bottom allows you to fully use the surface of granular activated carbon and to prevent the leakage of water containing oxidized impurities. The use of activated carbon is economical, provides quick and complete destruction of the residual active chlorine and due to the increased sorption properties in relation to oxidized impurities, which improves the quality of water. Next, the water is sent to the cathode chamber, in which the pH of the water and the shift of the redox potential to a level corresponding to the internal environment of the human body are regulated. An additional tank, which is installed on the water supply line between the filter and the entrance to the anode chamber, is filled with food grade granular ion-exchange Na-cation exchange resin with an exchange capacity of 3-6 g-equiv. This allows you to soften the treated water, to reduce the content of hardness salts in it, which significantly reduces the likelihood of the formation of insoluble metal hydroxides in the cathode chamber and thereby improves the quality of water treatment. The use of a resin with a higher degree of exchange capacity is impractical, since the indicated range is sufficient to obtain a stable result.

As a catalyst, granular activated carbon from coconut shell with the addition of silver can be used. It is advisable to use coal with a bulk density of 480-550 g / DM ³ impregnated with silver in an amount of 0.06-0.3 wt.%. These characteristics are optimal when treating fresh water, such activated carbon not only has increased catalytic activity and higher sorption capacity with respect to impurities, but also has an additional disinfecting and preserving effect due to the presence in the structure of granules of silver coal with catalytic activity and bactericidal properties. This can significantly improve the quality of water. In addition, the presence of silver allows to increase the service life of the device due to the fact that the development and growth of biological contaminants adsorbed in the pores of activated carbon is prevented. This effect is especially significant with periodic use of the device, since the pause mode increases the likelihood of fouling.

It is advisable to use layers of non-woven propylene with a throughput of 5 μm or more as filter material in the filter. The number of layers that determine the thickness of the filter varies based on the conditions of the problem being solved - the characteristics of the treated water. With a standard layer thickness of 5 mm, the number of layers can be from 3 to 6. This allows you to effectively purify water from suspended impurities, to exclude their effect on the hydraulics of the device and the electrochemical process, which ensures a stable high quality of treated water.

An additional sensor for the flow of treated water installed between the additional tank and the entrance to the anode chamber can additionally be placed on the overflow line. The presence of such a sensor makes it possible to introduce means of monitoring the total amount of water that has been treated and the timely replacement of elements that have exhausted their life.

The device of this utility model is shown schematically in FIG. one.

A device for electrochemical water treatment contains an electrochemical reactor, schematically shown in the diagram by one electrochemical cell 1, the interelectrode space of which is divided by a diaphragm 2 into anode 3 and cathode 4 of the chamber. The device contains a supply line of treated water 5, which is connected to the input of the anode chamber 3. On line 5, a filter 6 and an additional container 7 are installed in series, filled with food-grade granular ion-exchange Na-cation exchange resin. The output of the anode chamber 3 is connected by a flow line 8 to the input of the cathode chamber 4. On line 8, a tank 9 with a catalyst — granular activated carbon — is installed. The output of the cathode chamber 4 is connected to the line 10 of the outlet of the treated water.

The device operates as follows. The treated water, for example tap water, enters the filter 6 through line 5, in which the suspended impurities are cleaned and then fed to a container 7 filled with food-grade granulated ion-exchange Na-cation exchange resin. In tank 7, water softens and removes cations of hardness salts from it and replaces them with sodium cations. After the tank 7, water enters the anode chamber 3 of cell 1, in which due to the formation of oxidizing agents, mainly active chlorine, microorganisms are destroyed and organic impurities are oxidized. From the anode chamber 3, water enters the tank 9, filled with a catalyst - granular activated carbon, on which the residual active chlorine is destroyed and sorbed by oxidized organic impurities, after which the water enters the cathode chamber 4 of cell 1, in which the pH and redox potential are regulated to values corresponding to the values of the internal environment of a person. From the cathode chamber 4, the treated water is supplied to the consumer via line 10.

The form of the specific implementation of the elements of the device is selected depending on the conditions of the task to clean.

As electrochemical cells, we used cells made of vertical coaxial rod and cylindrical electrodes, lower and upper dielectric bushings, a ceramic diaphragm, coaxially placed between the electrodes and dividing the interelectrode space into the electrode chambers, and in the lower and upper bushings for supplying and discharging the processed medium channels provided with fittings are made into the chamber of the cylindrical electrode, the upper and lower collectors are fixed at the ends of the upper and lower bushings The rotary heads installed in the lower and upper heads, respectively, for supplying and discharging the medium to be processed into the chamber of the rod electrode, channels are provided with fittings, and the cell also contains a device for fixing the heads, and the fitting of the bushings and heads is connected to the devices for feeding and removal of the processed medium. The cells are made in accordance with the patent of the Russian Federation No. 2078737, C02F 1/461, 05.26.94.

An essential resource is the work resource, which determines the quantitative indicators of the filter material used, the amounts of activated carbon and ion-exchange resin. The device used removable vertical cylindrical tanks with a capacity of 1.36 liters each. One of them has a vertical three-layer filter made of non-woven polypropylene, with the feed of treated water to the center of the tank and filtering it from the center to the periphery. The thickness of one layer of polypropylene was 5 mm. The container with the catalyst was filled with activated carbon from coconut shell with a bulk density of 500 g / dm ³ impregnated with silver in an amount of 0.1 wt.%. The ion-exchange resin container contained a granular edible Na-cation exchange resin with an exchange capacity of 4 g-equiv.

The service life of the filter was 10,000 liters, or 6 months, the service life of the catalyst was 8,000 liters, but not more than 6 months, the life of the food-grade ion-exchange resin was 8,000 liters, but not more than 6 months. Depending on what comes earlier - the volume of treated water or the operating time, the elements are replaced by the same type, and the waste ones are sent for regeneration.

The productivity of the device was 50-60 l / h.

Treated water complies with the norms established by the legislation of the Russian Federation. The pH value is 6.9-7.1, the total mineralization is about 400 mg / l, the total hardness is not more than 5 mEq / l, the total number of bacteria in 1 ml is less than 50, the number of bacteria of E. coli is absent, the amount of suspended solids is absent . The indicated characteristics did not change during the entire operation of the device during the time of the experiment during the treatment of 6000 l of source water.

As follows from the above data, when using this utility model, the quality of water treatment is improved while maintaining the constant quality characteristics of the treated water.

Claims (4)

1. Device for electrochemical treatment of water, containing a diaphragm electrochemical reactor made of 1-2 vertical cylindrical electrochemical cells, each of which contains electrodes, the interelectrode space of which is divided by a ceramic diaphragm into an anode chamber and a cathode chamber with entrances to the bottom of the cells and exits to their upper part, the supply line of the treated water with a filter installed on it, connected to the input of the anode chamber, the overflow line connecting the output of the anode chamber with the input cathode chamber house, a container with a catalyst with an entrance at the top and an exit at the bottom, installed on the overflow line, a treated water drain line connected to the output of the cathode chamber, and an additional tank with an entrance at the bottom and an exit at the top, characterized in that granular activated carbon is used as a catalyst, an additional tank is installed on the water supply line between the filter and the entrance to the anode chamber and is filled with food-grade granular ion-exchange Na-cation exchange resin. 2. A device for electrochemical water treatment according to claim 1, characterized in that the container with the catalyst contains granular activated carbon from a coconut shell with the addition of silver. 3. A device for electrochemical water treatment according to claim 1, characterized in that the filter comprises a vertical cylindrical container with a filter material of nonwoven propylene 5 microns thick with an inlet at the top and an outlet at the bottom as a filter on the supply line. 4. A device for electrochemical water treatment according to claim 1, characterized in that the flow sensor is additionally located on the overflow line, installed between the additional tank and the entrance to the anode chamber.

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