RU123000U1 - DEVICE FOR ELECTROCHEMICAL WATER TREATMENT - Google Patents

Abstract

1. A device for electrochemical treatment of water for obtaining water with a given redox potential, containing a flow meter, an electrolyzer and a controller, characterized in that in front of the electrolyzer, a conductivity sensor of the source water is installed connected to the controller, which makes it possible to take into account the salinity of the source water when setting the operating modes of the electrolyzer, and a valve with an electric drive for adjusting the flow of source water, which makes it possible to automatically set and maintain the required flow of source water to obtain a given redox potential of the treated water. The device for electrochemical water treatment according to claim 1, characterized in that at the outlets of the catholyte and anolyte flow, RedOx potential sensors are installed, connected to the controller and allowing to take into account the value of the RedOx potential of the treated water when automatically adjusting the flow of source water. The device for electrochemical water treatment according to claim 1, characterized in that the controller has a connection according to standard protocols, preferably via RS-232 and / or GPRS or ETHERNET, for communication with a higher level automated system. The device for electrochemical water treatment according to claim 1, characterized in that a reservoir with a flushing liquid is connected to the inlet into the electrolyzer after a valve with an electric drive for adjusting the flow of source water through a solenoid valve for inlet of a flushing fluid connected to the controller, which allows automated technological flushing of the electrolyzer. five. The device for electrochemical water treatment according to claim 4, characterized

Description

The utility model relates to the field of electrochemical water treatment and is intended to produce water with a given redox potential, with the provision of automated washing of the electrolyzer. The device can also be used to purify tap drinking water from microorganisms of all types and forms, toxic organic compounds, heavy metal ions, the quantitative content of which in drinking water does not meet sanitary standards.

Known installation for the treatment of drinking water according to patent RU No. 2322395, IPC C02F 1/46, bull. No. 11 of April 20, 2008, containing a diaphragm electrochemical reactor, the electrodes of which are divided by a finely porous diaphragm into the anode and cathode chambers, a flotation reactor, and a catalytic reactor.

The disadvantages of this installation include the lack of an automated control system that sets the mode of operation of the installation, depending on the flow of the source water and the level of its electrical conductivity, which depends on the amount of substances dissolved in the water, and the inability to produce water with a given oxidation and reduction potential.

Known technical solution according to patent RU No. 51731, IPC G01F 1/06 dated 02.27.2006 placed in the installation for activating drinking water or in the electrochemical synthesis of anolyte with several sensors for water flow, catholyte, anolyte, saline, hydrochloric acid solution. All flow sensors are connected hydraulically to the corresponding pipelines of water-salt solutions or water in this installation and are electrically connected to one electronic circuit for signal processing and indication of parameters. The circuit is connected to the current and voltage sensors of electrochemical reactors included in the installation, electrically controlled by the reactor power unit and hydraulic control units (with electrically controlled valves or pumps for supplying water, saline and HC1 hydrochloric acid solution to the installation). The circuit is equipped with additional electronic control elements and a program for measuring and indicating anolyte parameters (flow rate, quantity, Sah, ORP, pH), more accurate automatic control and setting the required anolyte parameters (by measuring and controlling the flow rate of saline solution and catholyte flow rate in addition to monitoring anolyte flow rate and reactor current) and to control the operation of the installation, including its regeneration (flushing with HCl solution), by measuring and monitoring the flow rate of HCl solution and changes in voltage tori installation related to the cathode deposits. This installation is taken as a prototype.

The disadvantage of this installation is that the required parameters of the redox potential of the produced water are set based on the experimentally determined dependence of the activated water parameters on the water flow at various activator currents, which does not allow setting and maintaining the exact ORP values of the produced water, taking into account the quality of the source water depending on the amount of substances dissolved in it, since there are no necessary means of objective control such as a sensor e conductivity of the source water, sensors RedOx potential of anolyte and catholyte.

The technical problem solved by the utility model is to provide the ability to set and continuously automatically maintain the parameters of the redox potential of the water being treated by the installation, taking into account the quality of the source water, including remotely, to ensure automated washing of the electrolyzer with an acid solution in order to remove cathode deposits.

The essence of solving the technical problem lies in the fact that the device for electrochemical water treatment contains a controller for automated control, to which an input flow meter, a source sensor of conductivity of the source water and a valve with an electric drive to control the flow of source water are connected, which allows for the production of water with a given redox potential by means of an electrolyzer connected to a controller and including an electrochemical reactor for producing anolyte solutions (“Dead” water) and catholyte (“living” water), as well as mixing and catalytic reactors used in the purification of tap drinking water, and the electrolyzer switch to the catholyte and anolyte production mode, or drinking water purification. The controller provides a choice of the operation mode of the electrolytic cell, as well as control of the current strength of the electrolytic cell depending on the flow of the source water and the level of its electrical conductivity, which depends on the amount of substances dissolved in the water, and also controls the electric valve, adjusting the flow of the source water to set parameters of the electrolyzer. The RedOx potential sensors installed on the terminals of the catholyte and anolyte flow of the electrolyzer connected to the device control controller allow taking into account the value of the redox potential of the treated water during the automated control of the source water flow and setting the current strength of the electrolyzer. Depending on the application of the device autonomously or as part of a water treatment complex, the required operating mode of the device and the required RedOx potential of the treated water are set from the controller’s own remote control or from a higher-level control system through the controller’s connection using standard protocols, preferably via RS-232 and / or GPRS or ETHERNET. To carry out automated technological washing of the electrolyzer to the water inlet to the electrolyzer, after the valve with the electric drive adjusts the flow of the source water, which blocks the access to the cell of the source water during the technological washing, a washing liquid reservoir is connected through the washing fluid inlet solenoid valve connected to the controller. The conductivity sensor of the liquid discharged into the drain connected to the device control controller allows automatic flow control of the electrolyzer to control the passage of the washing fluid through the electrolyzer, as well as to control the final washing of the electrolyzer with source water. The level sensor installed on the tank with flushing fluid and connected to the controller allows you to control the presence of flushing fluid in the tank sufficient to carry out automated technological flushing of the electrolyzer and to promptly inform about the need for additional filling of flushing fluid into the tank. Three-way valves of the flow of anolyte and catholyte of the electrolyzer connected to the device control controller allow redirecting the waste water to the drain, depending on the selected operating mode of the electrolyzer, as well as discharge the washing liquid into the drain during technological washing of the electrolyzer.

The structural and functional diagram of a device for electrochemical water treatment is shown in figure 1, where are indicated:

1 - input of source water;

2 - flow meter;

3 - sensor conductivity of the source water;

4 - reservoir for flushing fluid;

5 - sensor level of flushing fluid in the tank;

6 - device control controller;

7 - connection using standard protocols, preferably via RS-232 and / or GPRS or ETHERNET for communication with a higher level system;

8 - catholyte RedOx potential sensor;

9 - three-way valve flow catholyte;

10 - output stream of catholyte;

11 - sensor conductivity of the liquid discharged into the drain;

12 - output flow of flushing fluid and water into the drain;

13 - output flow anolyte;

14 - three-way valve flow anolyte;

15 - sensor RedOx potential of the anolyte;

16 - electrolyzer;

17 - solenoid valve for entering the washing liquid;

18 - valve with electric control of the flow of source water.

A device for electrochemical water treatment works as follows. Water from the water supply system through the input 1 of the source water enters the inlet flowmeter 2, then through the valve 18 with the electric drive, it enters the electrolytic cell 16. The modified installation “Emerald-KF-Three in one” (www.izumrud.com) was used as the electrolyzer. com / emerald / models / emerald_kf3.php). In the electrolyzer, upon receipt of solutions of anolyte (“dead” water) and catholyte (“live” water), the water is processed in an electrochemical reactor, and in the purification of tap drinking water, additionally in mixing and catalytic reactors. The controller 6 provides the switching of the operating conditions of the electrolyzer 16, as well as controlling the current strength in the electrochemical reactor depending on the flow of the source water and the level of its electrical conductivity, and also controls the valve 18 with an electric drive, providing control of the flow of the source water. Installed after the three-way valve 9 of the catholyte stream, the catholyte RedOx potential sensor 8 and after the three-way valve 14 of the anolyte stream, the redOx potential sensor 15 of the anolyte, allow to measure the exact value of the RedOx potential of the treated water and take it into account when automatically adjusting the source water flow and setting the current in the cell by connecting the above sensors to the controller 6. Technological washing of the cell 16 in order to remove cathode deposits from it is carried out automatically after processing 40 0 to 500 liters of feed water, depending on the level of its electrical conductivity, which depends on the amount of substances dissolved in the water, when there is no consumption of water treated by the device (preferably at night). During technological washing, valve 18 with an electric drive to control the flow of source water blocks the access of source water to the electrolytic cell 16 for the duration of this washing, and the three-way valve 9 of the catholyte stream and the three-way valve 14 of the anolyte stream connected to controller 6 redirect the fluid flows from the exits of the electrolyzer 16 to conclusion to the drain 12. Through the solenoid valve 17 for entering the washing liquid connected to the controller 6, the washing liquid, preferably consisting of 15% p, enters the electrolyzer 16 from the tank 4 alignment acetic acid. When the controller 6 fixes, by means of the conductivity sensor 11 connected to it with platinum electrodes connected to it, changes in the conductivity of the liquid discharged into the drain, which indicates the passage of the washing liquid through the electrolyzer 16, the three-way valve 9 of the catholyte stream and the three-way valve 14 of the anolyte completely block the liquid outlet from the electrolyzer 16.

After that, after 60 minutes, the solenoid valve 17 for entering the washing liquid is closed, and the three-way valve 9 of the catholyte stream and the three-way valve 14 of the anolyte stream redirect the liquid flows from the exits of the electrolyzer 16 to the outlet to the drain 12 and the valve 18 is fully opened with the electric drive for adjusting the flow of the source water. After the conductivity of the source water and the water discharged into the drain are equalized, the final washing of the electrolyzer 16 with the source water is carried out for another 1 minute to completely remove from the system the residual washing liquid with the cathode deposits dissolved in it. Upon completion of this process, the device is again ready for electrochemical treatment of water. When using the device, the required mode of operation and the required RedOx potential of catholyte or anolyte are autonomously set from the controller 6’s own remote control, and when used as part of a water treatment complex, it is controlled by connecting the controller using standard protocols, preferably via RS-232 and / or GPRS or ETHERNET 7.

Claims (6)

1. A device for the electrochemical treatment of water to produce water with a given redox potential, comprising a flow meter, an electrolyzer and a controller, characterized in that an electrolysis sensor for the source water connected to the controller is installed in front of the electrolyzer, allowing to take into account the salinity level of the source water when setting the operation modes of the electrolyzer, and a valve with an electric drive to control the flow of source water, which allows you to automatically set and maintain the required flow of the source water water to obtain a given redox potential of the treated water. 2. The device for electrochemical water treatment according to claim 1, characterized in that at the terminals of the catholyte and anolyte flow there are installed RedOx potential sensors connected to the controller and allowing to take into account the value of the RedOx potential of the treated water during the automated adjustment of the source water flow. 3. The device for electrochemical water treatment according to claim 1, characterized in that the controller is connected according to standard protocols, preferably via RS-232 and / or GPRS or ETHERNET, for communication with an automated system of a higher level. 4. The device for the electrochemical treatment of water according to claim 1, characterized in that a reservoir with washing liquid is connected to the input to the electrolyzer after the valve with the electric actuator adjusting the flow of the source water through the solenoid valve for entering the washing liquid, which allows for automated technological washing electrolyzer. 5. The device for the electrochemical treatment of water according to claim 4, characterized in that a conductivity sensor for the liquid discharged into the drain connected to the controller is installed at the outlet of the washing liquid and water flow into the drain, which allows for automated washing of the electrolyzer to control the passage of washing liquid through electrolyzer, as well as control the final washing of the electrolyzer with source water. 6. The device for the electrochemical treatment of water according to any one of claims 4 and 5, characterized in that a washing liquid level sensor in the tank is connected to the controller, allowing to control the presence of washing liquid in the tank, sufficient for automated technological washing electrolyzer, and timely inform about the need to add flushing fluid to the tank.