EA013774B1 - Device for the electrochemical treatment of the water and the water solutions - Google Patents

Abstract

The invention relates to electrochemical treatment of water and salts aqueous solutions aimed at changing properties thereof and can be used for purification, decontamination and water activation and producing washing, disinfecting, sterilizing and preserving solutions and also cathode softening of the water. A device comprises an external electrode 1 made in the form of the hollow cylinder, inside which there is an internal electrode 2. Between the electrodes there is the semi-permeable diaphragm 3 dividing the electrode space into the internal 4 and exterior 5 electrode chambers. Dielectric sleeves 6 and 7 are arranged on the external electrode ends. Accordingly, outer 8 and inner 9 channels are provided on the sleeves communicating with an exterior electrode chamber 5. The internal electrode 2 has holes 10-12 connecting the internal electrode cavity with the internal electrode chamber 4. There is at least one partition inside the interior electrode. The technical result of the invention is the increased efficiency, expansion of the range of the produced pH and the oxidation-reduction potentials of the treated water, the increased service life of the device, reduction of the labor input at the device installation and repairs, the decreased power input at the device operation, increase of store life of the produced disinfecting, sterilizing and washing solution properties.

Description

The invention relates to the field of electrochemical treatment of water and aqueous solutions of salts with the aim of changing their oxidative, reducing and structural properties. The invention can be used for cleaning, disinfecting and activating water, obtaining detergents, disinfectants, sterilizing and preservative solutions, as well as cathodic softening of water.

There are various types of devices for the electrochemical treatment of water, containing an outer cylindrical electrode, inside which there is an internal electrode, where a semi-permeable diaphragm is placed between the electrodes, which divides the electrode space into the inner and outer electrode chambers [Japan Application No. 1-104387, cl. S02R 1/46, 1989, Patent of Russia No. 2078737, cl. S02P 1/46, 1997].

Obtaining the required technical result is hampered by the limited functionality of the devices, which do not allow to obtain solutions with a given redox potential in a wide range and different pH values.

A device for the electrochemical treatment of water or aqueous solutions is known, comprising an outer electrode in the form of a hollow cylinder, inside which a cylindrical inner electrode is coaxially located, a semi-permeable diaphragm separating the electrode space into an inner and outer electrode chambers coaxially located between the electrodes, the inner electrode chamber being directly connected channel for supplying fluid [Patent of Russia No. 2145940, cl. C02R 1/461, 2000].

Obtaining the required technical result is hampered by the limited functionality of the device for organizing hydrodynamic fluid flows, which do not allow to obtain high flow rates of the treated fluid and the required values of salinity, which significantly reduces the durability of the product and the quality of the solutions obtained.

A device for the electrochemical treatment of water or aqueous solutions is known, which contains an outer tubular electrode, inside which an internal electrode is located, a semi-permeable diaphragm is placed between the electrodes, which separates the electrode space into an inner and outer electrode chambers, an outer electrode chamber is connected through holes in the lateral surface of the outer cylindrical electrode input and output channels in the internal electrode is made of at least one hole connecting the internal th camera with a channel for the removal of fluid [Patent of Russia № 2132821, cl. S02R 1/46, 1999].

Obtaining the required technical result is hampered by the limited capabilities of the device, which do not allow obtaining solutions with a given redox potential and pH in a wide range, low productivity, complexity of installation and repair, and a short product life.

The closest set of essential features (prototype) of the utility model is a device for electrochemical treatment of water or aqueous solutions, containing an outer electrode in the form of a hollow cylinder, inside which a cylindrical internal electrode is located coaxially, a semi-permeable diaphragm is placed coaxially between the electrodes, which separates the electrode space and external electrode chambers and dielectric bushes mounted on the ends of the external electrode on the surface Lock are derived, respectively, the inlet duct and an outlet communicating with the outer electrode chamber, the inner electrode is provided with holes connecting the cavity of the inner electrode with an inner electrode chamber [Russian Patent № 2176989, cl. C02P 1/461, 2001].

Obtaining the required technical result is hampered by the limited capabilities of the device, which do not allow to obtain solutions with a given redox potential in a wide range, low productivity, complexity of installation and repair.

The claimed invention is directed to solving the problem of creating a device for the electrochemical treatment of water or aqueous solutions with high performance, convenient in operation.

The technical result obtained when implementing the claimed invention is expressed in increasing productivity, expanding the range of obtained pH and redox potentials of treated water and water-salt solutions, increasing the reliability of the device, increasing the service life, reducing labor costs during installation and repair of the device, reducing energy consumption when operating the device, increasing the compactness of the device.

The technical result obtained during the implementation of the claimed invention is expressed in increasing productivity, expanding the range of the obtained pH and redox potential of the redox potential of the treated water and water-salt solutions, namely, decontaminated and activated drinking water, disinfectants, sterilizing and washing solutions, improving the reliability of the device, increasing the service life, reducing labor costs during installation and repair of the device, reducing energy consumption during operation e device increases retention time properties of the obtained disinfectant, sterilizing and washing solutions.

To achieve the above technical result in a device for the electrochemical treatment of water or aqueous solutions containing the outer electrode in the form of a hollow cylinder, inside which the cylindrical inner hollow electrode is coaxially located, is semi-permeable

- May 1, 13774 a diaphragm coaxially placed between the electrodes with separation of the electrode space into the inner and outer electrode chambers and dielectric bushings mounted on the ends of the outer electrode where the input channel and the output channel are connected to the surface of the sleeves, respectively, communicating with the outer electrode chamber where the internal electrode is made with holes connecting the cavity of the internal electrode with the internal electrode chamber, inside the internal electrode is placed at least one nepron -permeable or low permeable partition.

A partition placed inside the internal electrode divides the cavity of the internal electrode into two parts, changing the hydrodynamic flows and changing the flow rate of the liquid and, accordingly, the processing time of the liquid in the internal chamber of the device. By changing the hydrodynamic flows, the productivity increases, the range of the resulting pH and the redox potential of the ORP (redox potential) of the treated water or solutions expands, and the time taken to preserve the properties of the resulting disinfecting, sterilizing and washing solutions is increased. Due to the constructive performance increases the reliability of the device, increases the life, also reduces labor costs during installation and repair of the device.

In the particular case of carrying out the invention in a device for the electrochemical treatment of water or aqueous solutions, the partition is placed in the inner cavity of the inner electrode with the division of the volume of the inner electrode into two unequal parts: input and output, and the output part of the internal electrode is smaller than the input part.

In the particular case of carrying out the invention in a device for the electrochemical treatment of water or aqueous solutions, the partition is placed in the internal cavity of the internal electrode with the separation of the internal electrode into two equal parts: the input and output, and the output part of the internal electrode is equal to the input part.

In the particular case of the invention in a device for the electrochemical treatment of water or aqueous solutions, the partition is placed in the inner cavity of the internal electrode with the division of the volume of the internal electrode into two parts: input and output, and in the output part of the internal electrode one outlet is made, and in the input part of the internal the electrode is made inlet.

In the particular case of carrying out the invention in the inlet part of the inner electrode is additionally made a group of at least two holes, and the distance between the holes in the hole group is smaller than between the inlet and the first hole in the specified hole group.

In the particular case of carrying out the invention in the input part of the internal electrode is additionally made a group of holes, and the axis of the holes included in the specified group are located along a helical line along the side surface of the electrode or on a straight line forming the outer cylindrical surface of the electrode.

In the particular case of the invention, the device for the electrochemical treatment of water or aqueous solutions is provided with diaphragm fasteners mounted on the ends of the dielectric bushings.

In the particular case of carrying out the invention in the device for the electrochemical treatment of water or aqueous solutions at the ends of the internal electrode is installed sleeve, the axial holes of which form the input and output channels.

In the particular case of carrying out the invention in a device for the electrochemical treatment of water or aqueous solutions, the inner electrode is the anode, and the outer electrode is the cathode.

The invention is illustrated by drawings, where in FIG. 1 schematically shows a device for the electrochemical treatment of water or aqueous solutions;

in fig. 2 schematically shows the flow of the treated liquid with one of the options for processing the liquid;

in fig. 3 schematically shows the flow of the treated fluid in the second variant of the treatment fluid.

A device for the electrochemical treatment of water or aqueous solutions contains an outer electrode 1 in the form of a hollow cylinder, inside which is located the inner electrode 2, between the electrodes there is a semipermeable diaphragm 3 dividing the electrode space into the inner 4 and outer 5 electrode chambers (Fig. 1). The dielectric bushings 6 and 7 are installed on the ends of the external electrode 1. The input channel 8 and the output channel 9 are connected to the surface of the bushings, respectively, communicating with the external electrode chamber 5. The internal electrode 2 is made with holes 10-12 that connect the cavity of the internal electrode with the internal electrode chamber 4. Inside the internal electrode is placed at least one partition (plug) 13. The partition divides the cavity of the internal electrode 2 into two parts - the input 14 and the output 15. In some cases, the output Part of the inner electrode 15 is smaller than the input portion 14. The input portion 14 and output portion 15 of the inner electrode, in some embodiments, may be equal.

In some examples, in the output part of the internal electrode 15 made one

- 2,013,774 outlet 12, and inlet 14 of the internal electrode is made inlet 10. In the entrance of the inner electrode 14 can be made a group of holes 11, and the distance between the holes 11 in the group of holes is smaller than between the inlet 10 by the first hole 11 in the specified hole group. In some embodiments, the execution axis of the holes 11 are located in a helix along the side surface of the electrode or on a straight line forming the outer cylindrical surface of the electrode.

The device is equipped with mounting diaphragm 16 and 17, mounted on the ends of the dielectric sleeves 6 and 7, respectively.

At the ends of the inner electrode 2 mounted bushings 18 and 19, the axial holes which form the input 20 and output 21 channels.

Between the sleeve 19 and the mounting of the diaphragm 17 is placed the contact 22 for connecting the internal electrode 2 to the power supply. The outer electrode 1 is connected to the power supply using an elastic metal bracket with a contact that is worn on the outer surface of the outer electrode.

The electrodes 1, 2 and the diaphragm 3 are fixed, hermetically and strictly coaxially using the sleeves 16, 17 of the dielectric material, using the sleeves 18 and 19 and the elastic sealing rings 23, 24, 25, 26 and 27.

Depending on the functional use, the inner electrode may be the cathode, and the outer electrode may be the anode and vice versa, the inner electrode chamber may be working, and the outer electrode chamber may be auxiliary and vice versa.

The device works as follows.

Depending on the solution with which properties and parameters it is necessary to obtain, different variants of hydraulic schemes are applied.

The first version of the treatment fluid. The treated liquid or brine under pressure through the inlet channel 20 enters the inlet part 14 of the internal cavity of the internal electrode 2 (Fig. 2). Passing through the internal cavity of the internal electrode, part of the liquid through the holes 10-11 immediately enters the internal electrode chamber 4. Another part of the liquid rests against the partition 13, as a result, an overpressure is created in the internal cavity of the internal electrode 2 and the liquid rushes through the holes with even greater pressure 11 into the inner electrode chamber 4. Filling the inner electrode chamber 4, the liquid or solution through the outlet 12 enters the outlet part 15 of the inner cavity of the inner electrode. Next, through the output channel 21, the treated solution is directed to the inlet channel 8 of the sleeve 6 into the outer electrode chamber 5. After passing through the outer electrode chamber 5, the fluid through the outlet channel 9 leaves the outer electrode chamber 5 and is fed into the inlet channel 20, under pressure through the inlet channel 20 enters the input part 14 of the inner cavity of the inner electrode 2 (Fig. 2). Passing through the internal cavity of the internal electrode, part of the liquid through the holes 10-11 immediately enters the internal electrode chamber 4. Another part of the liquid rests against the partition 13, as a result, an overpressure is created in the internal cavity of the internal electrode 2 and the liquid rushes through the holes with even greater pressure 11 into the inner electrode chamber 4. Filling the inner electrode chamber 4, the liquid or solution through the outlet 12 enters the outlet part 15 of the inner cavity of the inner electrode 2, a voltage is applied to the electrodes in such a way that electrode 2 is an anode, and electrode 1 is a cathode. Under pressure, the solution through the semi-permeable diaphragm 3 enters the external electrode chamber 5, and then through the output channel 21, the treated solution is taken to consumers. Electrode polarity variations can be different: the external electrode is the cathode, and the internal one is the anode, and vice versa, the external electrode is the anode, and the internal electrode is the cathode.

Another treatment option is fluid. The treated liquid or brine under pressure through the inlet channel 20 enters the inlet part 14 of the inner cavity of the inner electrode 2 and in the inlet channel 8 enters the outer chamber 5 of the outer electrode 1 (Fig. 3). Passing through the internal cavity of the internal electrode, part of the liquid through the holes 10-11 immediately enters the internal electrode chamber 4. Another part of the liquid rests against the partition 13, as a result, an overpressure is created in the internal cavity of the internal electrode 2 and the liquid rushes through the holes with even greater pressure 11 into the inner electrode chamber 4. Filling the inner electrode chamber 4, the liquid or solution through the outlet 12 enters the outlet part 15 of the inner cavity of the inner electrode 2, and then through the output channel 21 of the treated solution is taken for consumers, and the other part of the solution is directed to the output channel 8 of the sleeve 6. The electrodes are energized so that electrode 2 is the anode and electrode 1 is the cathode. Under pressure, the solution through the semipermeable diaphragm 3 enters the external electrode chamber 5 and is taken to consumers through channel 9.

Electrode polarity variations can be different: the outer electrode is the cathode, and the inner anode, and vice versa, the outer electrode is the anode, and the inner electrode is the cathode.

Depending on the properties of the solution to be obtained, water and / or various salt solutions are fed into the device.

Channel 20 is designed to supply treated water or saline. Channel 21 is designed to drain the treated fluid. Channel 9 is designed for removal of catholyte or saline.

To obtain catholyte, a solution of sodium chloride or other salt solutions and / or water is fed into the channel 20, the solution enters the internal electrode chamber 4. Through the holes 10-11, the electrodes are energized so that electrode 2 is the anode and electrode 1 is the cathode . Under pressure, the solution through the semipermeable diaphragm 3 enters the external electrode chamber 5. During operation, the device produces two oppositely charged ion fluxes on the outer and inner surfaces of the diaphragm 3, a potential difference arises between the streams, the charged streams increase the electric field intensity in the diaphragm by 35-50 In / cm ² , as a result, the mobility of ions in the pores of the diaphragm increases and the electrical resistance of the device decreases. The result is an electroactivated fluid solution (aquaeha®), which is output through channel 9, and a catholyte solution, which is output through channel 21. Electrode polarity variations may be different: the outer electrode is the cathode, and the inner one is the anode, and vice versa, the outer electrode is the anode, and the internal - the cathode, respectively, the catholyte can exit from the channel 9 and the electroactivated liquid solution (aquaeha®) can leave the channel 21.

In order to obtain disinfecting solutions, it is possible that the channel 20 supplies water, which flows into the internal electrode chamber. Channel 8 is supplied with a 30% solution of sodium chloride, which circulates in the cavity of the outer electrode chamber 5 using channel 9 to drain this solution into a container with saline solution, which is then used as a source of solution for feeding it back to the device through channel 8. Water passing through the internal electrode chamber 4, is outputted through channel 21 in the form of aquaeha®.

Electrode polarity variations can be different: the outer electrode is the cathode, and the inner anode, and vice versa, the outer electrode is the anode, and the inner electrode is the cathode. Due to the possibility of changing the polarity of the electrodes, there are no problems with cathode deposits and salt deposits on the membrane, which is a significant advantage for increasing the reliability and durability of the device. Cathodic deposits that may occur during operation are removed by changing the polarity of the electrodes, which ensures ease of maintenance of the device during operation.

The implementation of the internal electrode in 2 in the form of a hollow cylinder with side holes drilled along its entire length, and the use of the internal electrode chamber 4 as a channel for supplying liquid allows the internal and external surfaces of the electrode to be fully utilized in the electrochemical process, which dramatically increases the plant's performance, This saves the material of the electrodes. This allows you to extend the range of characteristics of the treated water and / or solutions.

The diaphragm located between the anode and the cathode makes a major contribution to the electrical resistance of the device. Effective use of the surface of the diaphragm allows to reduce the electrical resistance and, therefore, make the installation less energy-intensive. Changing the diaphragm with different permeability, you can get solutions with different pH values and redox potential.

The presence of an impermeable or weakly permeable partition 13 in the internal cavity of the internal electrode changes the hydrodynamics of the flow of the treated fluid, forming turbulence for turbulent mixing in the volume, which ensures a high degree of mixing of water in the chambers, which allows for the processing of all the microvolumes of water in the diffuse part of the electrical double layer at the interface electrode-electrolyte phases. Unlike the analogue, where it is possible to pass a part of the liquid without treatment, all the treated liquid enters the internal electrode chamber, which increases the processing performance.

The design of the device allows to reduce the number of conjugated and sealed parts and, consequently, increases the reliability of the device.

Installation and repair of the device is very simple. The sleeves 6 and 7 are put on the outer electrode 1 at both ends, then a diaphragm 3 is inserted into the outer electrode 1 with sealing rings 23 and 24 put on it. O-rings 25 and 26 are inserted into the grooves of the sleeves 6 and 7. Then the inner electrode 2 is inserted. The contact 22 is put on the upper part of the internal electrode, then the sealing ring 27 is put on the upper part of the internal electrode over the contact 22. Thereafter, the sleeves 18 and 19 are screwed on the upper and lower parts of the internal electrode so that g The tightness of the device connections. Lastly, an elastic bracket is inserted into the outer electrode 1 with a contact for connecting the outer electrode 1 to the power supply.

An example of the device.

The diameter of the inner surface of the outer electrode is 16 mm. The diameter of the working part of the inner electrode is 8 and 5 mm, respectively, since the inner and outer surfaces of the electrode are involved in the inner electrode. Interelectrode distance 4 mm. These diameters provide optimal contact conditions for each volume of the flowing solution or water to

- 4 013774 the top of the diaphragm. The diaphragm is made of ceramic. It is possible to manufacture the diaphragm from other materials resistant to aggressive media. The diaphragm may have a different thickness and permeability depending on the properties of the solutions to be obtained. The cathode of the device is made of stainless steel, titanium, glass carbon, electrically conductive and acid-resistant materials, platinum, niobium. The cathode is coated with platinum, iridium, oxides of ruthenium, cobalt and other materials. The anode is made of titanium, niobium, platinum, tantalum, graphite and is coated with platinum, iridium, ruthenium oxides or other metals.

Impermeable wall 13 can be made of metal, plastic, inert composite materials. Low permeable wall 13 may be made of metal, ceramic or plastic, which have holes.

Using the device, it is possible to obtain solutions with pH values from 3 to 11 and redox potential from -950 to +1200 mV. The table presents the comparative characteristics of the claimed device and currently produced analogues.

Parameters and characteristics of devices for electrochemical water treatment

Options Devices Analogue (patent number 2145940) Claimed Volumetric flow rate, cm ³ / s 2.8-8.3 3-12 Linear flow rate, cm / s 5.8-24 5-44 Water treatment time, with 0.8-3 0.5-6 Current, A 3-8 1.5-30 Voltage, V 10-24 12-120 Water salinity, g / l 0.5-5.0 0.1-5.0 Specific amount of electricity, C / l 360-2880 360-3000 The amount of treated fluid, l / hour 60 80 Resource of continuous work, h 15,000 25,000

These tables clearly show the higher characteristics of the claimed device in comparison with analogues.

According to the examples set out in the Russian patent № 2145940, the volumetric flow rate of the treated fluid is 5.5 cm ³ / s, voltage 7-20 V, current strength from 5 to 10 A, attainable mineralization of 0.27-0.7 / g / l

Characteristics of the claimed device: flow rate 3-12 cm ³ / s, current 1.5-30 A, voltage 30-120 V, mineralization 0.1-5 g / l.

The operation of the device according to the invention is carried out with a volumetric flow rate exceeding the flow rate indicated in the Russian patent No. 2145940.

Comparison of flow rate and salinity indices allows us to talk about achieving higher technical results than in the device analogues.

Claims (6)

CLAIM 1. A device for the electrochemical treatment of water or aqueous solutions containing an external electrode in the form of a hollow cylinder, inside which an internal electrode in the form of a hollow cylinder is located coaxially, a semi-permeable diaphragm separating the electrode space into the internal and external electrode chambers is placed coaxially between the electrodes, mounted on the ends of the external electrode, the input channel and the output channel communicating with the external electrode chamber are brought to the surface of the bushings, respectively The internal electrode is made with holes connecting the cavity of the internal electrode with the internal electrode chamber, and the input and output holes at the ends, characterized in that at least one impermeable or weakly permeable wall is located inside the internal electrode. 2. The device according to claim 1, characterized in that the partition is placed in the inner cavity of the internal electrode with the separation of the internal electrode into two unequal parts: the input and output, and the output part of the internal electrode is smaller than the input part. 3. The device according to claim 2, characterized in that in the inlet part of the inner electrode a group of at least two holes is additionally made, and the distance between the holes in the hole group is smaller than between the input hole and the first hole in the specified hole group, and the output part of the inner electrode is additionally made at least one hole. 4. The device according to claim 2, characterized in that in the input part of the inner electrode a group of holes is additionally made, and their axes are located along a helix along the side surface of the electrode or on a straight line forming the outer cylindrical surface of the electrode. 5. The device according to claim 1, characterized in that it is provided with a diaphragm fasteners mounted on the ends of the dielectric bushings. - 5 013774 6. The device according to claim 1, characterized in that the ends of the inner electrode are mounted sleeves, combined, respectively, with the input and output holes, and the axial holes of the sleeves form the input and output channels.