RU95329U1 - INDUCTION ELECTROCHEMICAL INSTALLATION - Google Patents

Abstract

1. An induction electrochemical plant containing at least one electrochemical cell having electrode chambers separated by ion-exchange membranes: cathode and anode chambers for pumping electrolyte with inlet and outlet nozzles and working chambers: for producing catholyte with an outlet nozzle, for producing anolyte with an outlet branch pipe and a central chamber for obtaining a deionized solution with inlet and outlet pipes, the chambers are enclosed in a dielectric housing, the ion-exchange membranes separating the electrode and working chambers are made bipolar, as well as a device for inducing an alternating voltage (current) component, made in the form of a transformer, primary the winding of which is connected to the AC network, and the secondary windings are made of dielectric tubes wound in pairs bifilar and connected respectively to the input and output pipes of the mixer, which, in turn, is connected to a device for inducing a constant voltage (current) component; at the same time, the electrode cathode chamber of the electrochemical cell, connected to the corresponding secondary windings of the transformer, forms a cathode hydraulic circuit, and the electrode anode chamber, connected to the device for inducing a constant voltage (current) component, forms an anode hydraulic circuit; in addition, the electrochemical cell additionally contains six diaphragms forming six additional chambers, while the first, fifth and ninth chambers are designed for electrolyte pumping, each of them has inlet and outlet pipes, the second and eight

Description

The utility model relates to the field of applied electrochemistry, namely to the hardware of electrochemical technologies for the separation of liquids by ionic composition, and purification of impurities of inorganic and organic origin at an increased concentration of the initial solution, purification and separation of electrolyte mixtures using ionite membranes.

A device is known [see Patent No.RU 2100286 C1 Pushnyakov Nikolay Karpovich, Naida Nikolay Nikolaevich “Method of water disinfection and device for its implementation” Application: 96123069/25 Date of filing: 1996.12.11.] for water disinfection, containing two electrolysers, while electrolyzers equipped with cation exchange membranes and having connections from the metering tanks at the inputs to the anode chambers, and connected to each other so that the output from the anode chamber of the first electrolyzer is connected to the inputs to the anode and cathode chambers of the second electrolyzer, the output from the anode chamber the second electrolyzer is connected to the mixing chamber with the source of treated water entering the first electrolyzer, and the conclusions from the cathode chambers of the first and second electrolysis cells are the output paths of the solutions obtained in the electrochemical device.

As a prototype of the selected induction electrochemical installation [see Utility Model Patent RU No. 81189 IPC 2006.01 C25F 1/48, С25В 9/00, С25В 11/00 dated 09/22/2008, publ. March 10, 2009]. The installation comprises a transformer for inducing an alternating component of voltage (current), the primary winding of which is connected to an alternating current network, and the secondary windings are made of dielectric tubes wound in pairs bifilar, filled with electrolyte and connected respectively to the input and output nozzles of the mixer, which is connected to the nozzles of the device for inducing a constant component of voltage (current), made on the basis of two unipolar generators with a liquid rotor, as well as electroche ical cell. The electrochemical cell is divided by ion-exchange membranes into electrode chambers: anode and cathode for pumping electrolyte with inlet and outlet nozzles and working chambers: for producing catholyte with an outlet nozzle, for receiving anolyte with an outlet nozzle, a central chamber for receiving a deionized solution with an inlet and outlet nozzles. The electrode cathode chamber of the electrochemical cell, connected through a pump to the corresponding secondary windings of the transformer, forms a cathode hydraulic circuit. An anode hydraulic circuit is formed by connecting a device to induce a constant component of voltage (current) through a pump with an electrode anode chamber of an electrochemical cell. In the particular case, the electrolyte filling the hydraulic circuits is a saturated solution of NaCl. This device is the closest to the invention in technical essence and the achieved effect, therefore, selected for the prototype.

The disadvantages of the prototype are: the inability to purify water and aqueous solutions from impurities of inorganic and organic origin, complex in composition. In addition, chambers for producing catholyte and chambers for producing anolyte have only outlet pipes for discharging catholyte and anolyte, respectively, which limits the possibility of using this device to solve various technological problems of electrochemical cleaning, separation and separation of various impurities.

The objective of the utility model is to create a compact multifunctional, reliable and relatively cheap electrochemical installation that allows to improve the design, reduce the cost of manufacturing the device and expand its use for cleaning water and aqueous solutions from inorganic and organic impurities having a complex composition by reducing the total number of parts and variations in the configuration of the device depending on the task and the required performance, and also ensure zmozhnost of water nonchemical and purification of aqueous solutions of the impurity element, using electrocoagulation processes in a diaphragm cell with ion exchange membranes and the insoluble electrode, with release ionite or bipolar membranes, i.e. to separate impurity ions with a change in the phase state (when the pH of 9-14 in the cathode chamber reaches, salts of all metals except alkaline precipitate in the form of a fine precipitate, which is then easily removed by filtration or centrifugation).

The technical result achieved by solving the problem lies in the fact that not an electrodialyzer, but an electrocoagulator was introduced as a load into the induction electrochemical installation, which allows a number of electrochemical processes impossible when using an electrodialyzer. In addition, the inventive device can serve not only for the separation of liquids by ionic composition, but also for the selective separation of the individual components of the initial mixture, depending on the frequency of the supply current, and in the presence of several electrochemical plants, it is possible to increase the productivity of the entire complex.

The specified technical result is achieved as follows:

The inventive utility model, like the prototype, contains at least two or more electrochemical cells having two chambers separated by an ion-exchange membrane. Unlike the prototype, the electrochemical installation does not have a central chamber. A device for inducing an alternating component of voltage (current), made in the form of a transformer, the primary winding of which is connected to an alternating current network, and the secondary windings are made of dielectric tubes wound in pairs bifilar and connected respectively to the input and output pipes of the mixer-drive connected to the device to induce a constant component of voltage (current). In this case, only one pair of liquid electrodes (anode and cathode) is used, and the intermediate electrodes are replaced by bipolar membranes. In addition, to expand the range of possibilities for solving electrochemical problems, pairs of cathode and anode chambers are equipped with separate inlet and outlet pipes. In this case, the electrode cathode chamber of the electrochemical cell connected to the corresponding secondary windings of the transformer forms a cathode hydraulic circuit, and the electrode anode chamber connected to a device for inducing a constant component of voltage (current) forms an anode hydraulic circuit.

The number of electrochemical cells is determined depending on the problem being solved and the required unit capacity.

Figure 1 shows a functional diagram of an induction electrochemical installation.

The installation comprises a transformer 1 for inducing an alternating component of voltage (current), the primary winding 2 of which is connected to an alternating current network, and the secondary windings 3 are made of dielectric tubes wound in pairs bifilar, filled with electrolyte and connected respectively to input 4, 5 and output 6, 7 nozzles of the mixer 8, which is connected to a device for inducing a constant component of voltage (current) 9, made on the basis of two unipolar generators with a liquid rotor, as well as electrochi cell 10. The electrochemical cell 10 is divided by ion-exchange membranes 18 into electrode chambers: cathode 16 and anode 15 for pumping electrolyte with inlet (lower tubes) and outlet (upper tubes) fittings (Fig. 1) and working chambers: for separating cations 11 s input (lower) and output (upper) nozzles and for the isolation of anions 12 with input (lower) and output (upper) nozzles. Bipolar membranes are installed between each pair (anode and cathode) and working chambers instead of electrodes.

The device operates as follows: When a power supply is applied between the primary 2 and secondary winding 3 of the transformer 1, an electric field occurs. In the cathode circuit, the NaCl solution from the storage drive 8 through the nozzle 6 through the secondary winding 3-1 (w 21) is pumped through the nozzle 14 through the nozzle 14, the electrode cathode chamber 16, is discharged through the outlet nozzle 13 and through the bifilarly wound secondary winding of the transformer 3 -2 (w 22) is sent through the inlet pipe 4 to the mixer 8 for regeneration, while positive charged ions are concentrated in the electrode cathode chamber 16. In the anode circuit, the NaCl solution from the storage drive 8 through the nozzle 7, a device for inducing a constant component of voltage (current) 9, through an inlet pipe 36, an electrode anode chamber 15, an output pipe 32 is pumped by a pump 26 through a device for inducing a constant component of voltage (current) ) 9, made on the basis of two unipolar generators with a liquid rotor and through the nozzle 5, is returned to the mixer-drive 8 for regeneration, while negative charge is concentrated in the electrode anode chamber 15 pronounced ions. Thus, an electric field arises between the electrode cathode chamber 16 and the electrode anode chamber 15, under the influence of which the initial solution is processed both in the cathode chambers to obtain catholyte 11, and in the anode chambers to obtain anolyte 12. Thus formed package consisting of electrode anode and cathode chambers, a set of cathode and anode working chambers between which separation membranes are laid (depending on the task, cationic or anionitic) is compressed using studs and other back focus lock plate 31 through the insulating rubber gasket 33 between the pairs of anode and cathode chambers instead of intermediate electrodes laid bipolar membrane and forms a multi-chamber, multi-cell with liquid electrodes.

Effect: increase the degree of purification of surface, technological and waste water and aqueous solutions from impurities of inorganic and organic origin of complex composition while reducing operating costs.

The utility model is illustrated by an example of a specific implementation and circuit diagram of the device. Obtained after purification and the initial solution according to atomic absorption analysis had the composition shown in table 1.

An example of technical performance.

1. Preparation and operation of the electrode system: A saturated HCl solution was poured into the mixer-drive 8 by a mark located on the housing, and an initial solution intended for cleaning and containing the components indicated in Table 1 was placed in the buffer tank 30, after which the pumps 25, 26 were turned on The electrolyte - saturated NaCl solution was pumped by pump 25 from the mixer-mixer 8 through the outlet pipe 7 along the cathode circuit through the secondary winding 3-2 (w 22), through the inlet pipe 14, the cathode electrode chamber 16, the outlet pipe 13 through the secondary winding 3- 1 (w 21) 3 connection 4 and returned to the mixer-mixer 8 for regeneration. From the mixer-mixer 8, the electrolyte - saturated NaCl solution was supplied through the nozzle 7 and the device for inducing the DC component of voltage (current) 9, made on the basis of two unipolar generators with a liquid rotor, the inlet pipe 36, into the electrode anode chamber, and through the outlet pipe 32 through a device for inducing a constant component of voltage (current) 9, pipe 5 and returned to the mixer-mixer 8 for regeneration.

2. Preparation and operation of the anode and cathode working loops:

The anode buffer tank 30 was filled with the initial electrolyte solution containing the ions indicated in Table 1, then the pump 28 was turned on and the chambers were filled to obtain anolyte 12 through the inlet pipe of the collector 19 of the anode chambers, the solution was returned to the buffer tank 30 through the outlet pipe of the collector 34.

The cathode buffer tank 29 was filled with a 5% HCl receiving solution, then the pump 27 was turned on and the chambers were filled to obtain 11 catholyte through the inlet pipe of the collector 20 of the cathode chambers, the solution was returned to the buffer tank 29 through the outlet pipe 35.

The indicated actions ensured the circulation of the initial (purified) and receiving solutions.

The electrochemical cell was supplied with an alternating asymmetric current of industrial frequency. The process was carried out at a current density of 0.5 A / dm ² for 20 minutes. In the working chambers for producing catholyte 11 and anolyte 12, concentration of the corresponding impurity ions from the solution being purified was observed.

The content of the components in the source and receiving solutions in the case of using an asymmetric current of a resonant frequency as a power source is presented in table 2.

According to atomic absorption analysis, the content of impurities in demineralized water meets the requirements of maximum permissible concentrations.

Induction Electrochemical Plant

Table 1. Sample number Elemental composition Source water, g / l (pH = 6) Purified water, g / l pH = 7 pH = 9 pH = 11.5 one Zn 9.98 3.97 0.12 2.5 10 ^-3 Fe 0.2 3.5 10 ^-3 9 10 ^-4 5.4 10 ^-4 Cu 0.01 1.2 10 ^-3 7 10 ^-4 3 10 ^-4 Ca 0.45 0.45 0.43 0.1 Mg 0.35 0.35 0.33 0.05 Na 10.67 10.04 9.19 9.01 2 Fe 21.9 Traces Zn 1.82 - Ni 0.45 - Mo 0.74 0.2 Cu 2,35 0.2 Cr ⁺⁶ 0.012 - 3 Cl ^- 1.76 2.7 10 ^-3 SO ₄ ^-2 2,53 3.6 10 ^-3 CO ₃ ^- 0.69 1.8 10 ^-3

Table 2. Elemental composition Source water, g / l The receiving solution, g / l frequency Hz Zn 2.5 · 10 ^-3 2.1 · 10 ^-3 737 Fe 5.4 · 10 ^-4 5.3 · 10 ^-4 574 Cu 3.4 · 10 ^-4 3.2 · 10 ^-4 1508 Sa 0.1 0.910 ^-1 1206 Mg 0.05 0.4 · 10 ^-2 2010 Na 9.01 8.9 4200 Note: In the case of separation of a given component at resonant frequencies in the receiving solution, the content of the remaining components is at the level of traces.

Claims (2)

1. Induction electrochemical installation containing at least one electrochemical cell having electrode chambers separated by ion-exchange membranes: cathode and anode for pumping electrolyte with inlet and outlet nozzles and working chambers: for producing catholyte with an outlet nozzle, for producing anolyte with an outlet a nozzle and a central chamber for producing a deionized solution with inlet and outlet nozzles, the chambers are enclosed in a dielectric housing, ion-exchange membranes separating the electrode and working chambers are made bipolar, as well as a device for inducing a variable component of voltage (current), made in the form of a transformer, the primary winding of which is connected to an alternating current network, and the secondary windings are made of dielectric tubes wound in pairs bifilar and connected respectively to the input and output nozzles of the mixer, which, in turn, is connected to a device for inducing a constant component of voltage (current); wherein the electrode cathode chamber of the electrochemical cell connected to the corresponding secondary windings of the transformer forms a cathode hydraulic circuit, and the electrode anode chamber connected to a device for inducing a constant component of voltage (current) forms an anode hydraulic circuit; in addition, the electrochemical cell additionally contains six diaphragms forming six additional chambers, while the first, fifth and ninth chambers are designed for pumping electrolyte, each of them has an inlet and outlet pipe, the second and eighth chambers are designed to produce catholyte, each of them has the outlet pipe for the removal of catholyte, the third and seventh chambers are designed to receive a deionized solution, each of them has an inlet pipe for supplying the initial solution and an outlet pipe for the drain yes deionized solution, the fourth and sixth chambers are designed to receive anolyte, each of them has an outlet pipe for drainage of the anolyte; the diaphragms between the first and second chambers, between the fourth, fifth and sixth chambers and between the eighth and ninth chambers are made in the form of bipolar membranes, and the diaphragms between the second, third and fourth chambers and between the sixth, seventh and eighth chambers are made in the form of ion-exchange membranes , characterized in that the device uses several pairs of anode and cathode working chambers to obtain catholyte and anolyte, each of which is additionally equipped with individual inlet and outlet pipes, which are combined into groups and form the input and output collectors, while several pairs of anode and cathode chambers are used, depending on the task to clean the initial solution from impurities of inorganic or organic origin and the required performance, between which bipolar membranes are installed that perform the function of intermediate bipolar electrodes. 2. Induction electrochemical installation according to claim 1, characterized in that the power supply is carried out by an alternating asymmetric current of industrial or resonant frequencies, depending on the task.