RU2084408C1 - Device for electrochemical treatment of water - Google Patents

Abstract

FIELD: purifying and decontamination of water, or production of detergents and disinfectants. SUBSTANCE: the device has on electrochemical cell made of coaxially aligned tubular and internal electrodes, tubular ceramic diaphragm, catalytic chamber; the catalytic chamber is installed inside the internal tubular electrode; the electrochemical cell is installed in stepped casings - the lower and upper ones - furnished with flexible sealing gaskets and cavities; the upper casing is furnished with an outlet pipe connection, and the lower casing- with two inlet pipe connections. The device has covers of dielectric material made with sealing combs, hole for discharge of water and a groove for axial fixing. The device also has an agitating mechanism made in the form of die sleeves with grooves at angle of 45 deg. towards the flow and installed in the electrode chambers with a space of 30 to 50 mm. With the aim of purifying of potable water the geometric dimensions of the cell satisfy ratio

Description

 The invention relates to chemical technology, in particular to devices for electrochemical water treatment and can be used to purify and disinfect water or to obtain detergent and disinfectant solutions.

 A device for water electrolysis is known (Japanese application 1-104 387 C 02 F 1 / 46.1989), consisting of a cylindrical electrolyzer with electrodes coaxially located in dielectric bushings and a diaphragm between them, dividing the internal space into the cathode and anode chambers. The device includes a direct current source. But the known device has large energy losses during water treatment with time-varying salinity, low reliability and durability.

The closest in technical essence to the claimed device is a device for electrochemical water treatment, (International application PCT / RU 93/00075, 1993, C 02 F 1/46) containing an electrochemical cell made of vertical coaxial cylindrical and rod electrodes installed in dielectric bushings, a ceramic diaphragm, coaxially mounted in the bushings between the electrodes and dividing the interelectrode space into the electrode chambers, and in the upper and lower bushings made channels for supply treated water in the rod electrode chamber, a current source connected to the electrodes through the switching unit, and means for supplying and discharging the treated water into the electrode chamber of an electrochemical cell. In this case, the rod electrode is made of variable cross-section, the diaphragm is made of ultrafiltration of zirconium oxide-based ceramics with the addition of aluminum and yttrium oxides and is set so that the geometric dimensions of the cell satisfy the ratios: S _S / S _B = 0.7 0.8, where S _S and S _{B are} the cross-sectional areas of the chambers of the rod and cylindrical electrodes, respectively.

But in the known device, due to the laminar flow of water, an unfavorable hydrodynamic regime is created in the electrode chambers, i.e. water movement in the electrode chambers occurs at a low level of velocities and, correspondingly, the number R _e, which predetermines the obviously laminar nature of the flow, which in turn makes it difficult to desorb the products of electrode reactions from the electrode surface and their transport in the bulk of the solution, slows down the redox processes and reduces the effectiveness of electrochemical reactions in electrode chambers.

 The use of a cathode made in the form of a rod of a smaller diameter with respect to the anode, and hence a significantly smaller area, leads to the necessity of organizing water flows between the working chambers of the electrochemical cell from the outside using hoses, placing the catalyst chamber outside the electrochemical cell, and increasing the relative current density at the cathode and increasing diffusion resistance of the process of recovery of chlorine at the cathode. As a result, the complete removal of active chlorine forming in the anode chamber of the reactor is not ensured (the organoleptic properties of water deteriorate), and the processability and reliability of the device are reduced.

 The use of bushings for separating chambers in an electrochemical cell significantly complicates and increases the cost of the device design, since it leads to the need for grooves on the tubular electrode for supplying and discharging water and increasing the wall thickness of an expensive electrode, complicating the assembly and disassembling of the electrochemical cell, and increasing the nomenclature of device parts.

 The use of collectors containing several sockets for connecting cells hydraulically increases the cost of construction, requires the manufacture of special collectors for each circuit, disassembly of the entire unit when replacing one cell, and the impossibility of determining a defective cell without disassembling the unit. The use of an external electrode as the anode makes it necessary to cover the inner surface of the cylindrical electrode with a protective coating against anodic dissolution, which is not technologically advanced and does not provide the required coating quality.

 The device also does not provide the removal of metal ions from water.

A device for electrochemical treatment of water is proposed, comprising an electrochemical cell made of coaxially arranged external tubular and internal electrodes, a tubular ceramic diaphragm, and a catalytic chamber, the inner electrode being made tubular, inside of which there is a catalytic chamber, and the electrochemical cell is installed in the lower and upper housings made stepwise and equipped with sealing elastic gaskets and cavities, and the upper case is equipped with a fitting m for removal, and the bottom two spigots supply device is also provided with caps of dielectric material formed with sealing combs, a hole for draining water and groove for axial locking, the device also comprises a mixing mechanism arranged in the form of matrix plugs, with the slots 45 ^o to the direction of flow and installed in the electrode chambers with a pitch of 30 to 50 mm, in the case of drinking water purification, the geometric dimensions of the electrochemical cell of the proposed device must satisfy the ratio S _k / S _a > 1.0, where S _k and S _{a are} the cross-sectional areas of the cathode and anode chambers, respectively, and a chamber with cation exchangers is installed between the anode and cathode chambers of the electrochemical cell to remove heavy metal ions from the water.

 In the proposed device, the inner electrode of the electrochemical cell is made in the form of a tube, which allows you to use the inner cavity of the electrode to ensure the flow of water between the cells of the cell and place the catalyst chamber inside the electrochemical cell, which reduces the dimensions of the device and increases its reliability, by eliminating additional devices for organizing the overflow water between the chambers and the catalyst chamber outside the electrochemical cell.

 The housings are stepped, providing a gap between the electrodes and the diaphragm, with elastic sealing gaskets, cavities and fittings for supplying and discharging water to the cell and flow between the chambers, while the elements determining the mutual radial and axial location, fixing the electrodes and ceramic diaphragm are made in one part housing, which allows to simplify the design, increase the manufacturability of assembly and disassembly, reduce the range of parts.

 The implementation of the supply holes in the electrode cavity on the housing allows to exclude the implementation of the supply cavity in the form of grooves and holes on the electrode and the need for a reciprocal electrode of variable cross section, eliminates the possibility of creating local voltage increases and uneven wear of the electrodes at the points of entry of water in the cell cavity, which makes it possible to increase manufacturability, use thin-walled smooth tubes for the manufacture of electrodes, increase the CMM.

The geometric dimensions of the electrochemical cell must satisfy the relation: S _k / A _a > 1.0 where S _k and S _{a are} the cross-sectional areas of the cathode and anode chambers, respectively.

 Such a ratio of the chamber areas provides an increase in the relative current density at the anode due to a decrease in the relative area of the anode, activation of electrochemical oxidation reactions at the anode, and ensuring the full extent of the water reduction reactions at the cathode due to an increase in the cathode area with respect to the anode.

 An anode located inside the cathode is used as an anode in an electrochemical cell, which makes it possible to use the outer surface of the electrode as an anode and increases the manufacturability of applying a protective coating to the outer surface of the electrode to prevent anodic dissolution of the electrode during the electrochemical process.

To seal and create overflow between the chambers, the device is equipped with a special cover made of dielectric plastic material with sealing scallops located on the outer diameter of the sleeve, an opening for water drainage and a groove for axial fixing of the sleeve relative to the electrode. The implementation of the device with a stirring mechanism, which is a matrix sleeve with slots at an angle of 45 ^o to the stream or an annular spiral, installed with a pitch of 30-50 mm along the length of the electrode chamber, both separately and in combination with each other, provides a smooth twist of the inner layers water and their mixing with layers of water and the surface of the electrodes, which leads to improved desorption of the products of electrode reactions from the surface of the electrode and their transport in the volume of the solution, accelerates the redox processes and increases the efficiency of electrochemical reactions in electrode chambers.

 In FIG. 1 shows a device for electrochemical water treatment; figure 2, 3 device for mixing the flow in the cells of the cell and the scheme of its installation in the cell.

A device for electrochemical treatment of water contains an electrochemical cell made of coaxially arranged, outer tubular 1 and inner 2 electrodes, a tubular ceramic diaphragm 3, a catalytic chamber 4, while the electrochemical cell is installed in the lower 5 and upper 6 housings, made stepwise and equipped with sealing gaskets 7, cavities 8, and the upper case is equipped with a fitting for the outlet 9, and the bottom with two fittings for the supply 10. The device is also equipped with covers 11 with sealing and scallops, a hole for draining water 12 and the groove 13. The axial locking device comprises a stirring mechanism 14, designed as a matrix of plugs with grooves at an angle of 45 ^o to the direction of flow and arranged in the electrode chambers in increments of 30-50 mm. The device operates as follows.

 Processed water from a pressure source, through a filter and a nozzle for supply 10, enters an electrochemical cell with a ceramic diaphragm 3 made of tubular electrodes of the external cathode 1 and internal anode 2, forming flow-through electrode chambers (anode and cathode). The water to be treated first enters the anode chamber, where the execution of the inner electrode 2 is tubular, allows its internal cavity to be used for the flow of water between the electrode chambers and to accommodate the catalytic chamber 4 through which the treated water passes after leaving the anode chamber.

 During the flow through the anode chamber, active chlorine is formed from salts, which make up the natural mineralization of water. Active chlorine compounds completely destroy all microorganisms and oxidize organic impurities.

 In the catalytic chamber 4, the destruction of active chlorine occurs. Next, the water enters the cathode chamber, where the redox potential is shifted, the biological value of the water increases, and high-quality purification is ensured.

 Special mixing mechanisms 14 with a step along the entire length of the electrode chambers provide mixing of the entire volume of water, increasing the efficiency of electrochemical reactions.

 The design of cases 5.6 allows the assembly of the device from individual electrochemical cells to increase productivity and processing efficiency.

 Thus, the claimed technical solution is simple in design, technologically advanced, has smaller dimensions and material consumption, is reliable in operation, has increased efficiency of electrochemical reactions, and generally increases the degree of water purification.

Claims (4)

 1. Device for electrochemical water treatment, including coaxially located external, which is the body, and internal electrodes separated by a tubular ceramic diaphragm with the formation of the anode and cathode electrode chambers, and a catalytic chamber, characterized in that the inner electrode is an anode made hollow and inside the catalytic chamber is placed, the external electrode is the cathode, the anode and cathode chambers are interconnected through the catalytic chamber, the device is equipped with holders, lined from opposite ends of the electrodes, made stepwise and provided with sealing elastic gaskets and cavities, moreover, one of the holders is equipped with a fitting for drainage, and the other with two water supply fittings, the device is equipped with two covers of dielectric material made with sealing scallops, a groove for axial fixation and one of the covers is provided with an opening for water drainage, the electrode chambers are equipped with a stirring device made in the form of rings with a groove made at an angle to the stream of water. 2. The device according to claim 1, characterized in that the grooves are drilled at an angle of 45 ^o to the flow of water.  3. The device according to claims 1 and 2, characterized in that the rings in the electrode chambers are placed at a distance of 30 to 50 mm from each other. 4. The device according to PP.1 to 3, characterized in that
S _k / S _a > 1,
where S _k the cross-sectional area of the cathode chamber;
S _a the cross-sectional area of the anode chamber.

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