WO2006043853A1

WO2006043853A1 - Device for producing electro-activated solutions

Info

Publication number: WO2006043853A1
Application number: PCT/RU2005/000153
Authority: WO
Inventors: Vladimir Vikentievich Vinogradov; Svetlana Yurievna Vinogradova; Vadim Veniaminovich Ustumenko
Original assignee: Vinogradov Vladimir Vikentievi; Svetlana Yurievna Vinogradova; Vadim Veniaminovich Ustumenko
Priority date: 2004-10-20
Filing date: 2005-03-30
Publication date: 2006-04-27

Abstract

The aim of the invention is to improve the serviceability of a device, in particular to develop a device which does not required to replace the entire positive electrode when the anode thereof is failed. The inventive device for producing electro-activated solutions comprised two bases an axial cylindrical anode arranged therebetween and a cathode which is disposed in a coaxial position with respect to the anode. A working chamber formed between the cathode and anode is divided into cathode and anode chambers by a semi-penetrable membrane coaxial thereto. A working reagent supplying pipe is fixed to one base and the anode is provided with an axial cavity which is embodied therein and connected to said working reagent supplying pipe and to the anode chamber by means of channels. The anode chamber is connected to an anolyte-discharging pipe and the cathode chamber is connected to a catolyte-discharging pipe. Said device is also provided with a threaded current lead which connects the anode to the base. The novelty of the inventive device distinguishing it from a prototype lies in that the anode is embodied in the compound through the height form and consists of two equal parts. Said current lead is connected to the base to which the smaller part of anode is adjacent. The threaded current lead is also used for fixing the anode to the base. The cathode is connectable to the base by producing a tight contact between the internal surface thereof and the side surface of the base.

Description

DEVICE FOR RECEIVING

ELECTROACTIVATED SOLUTIONS

Technical field

The utility model relates to the electrochemical industry, and can be used in the production of electroactivated solutions (catholyte and anolyte).

State of the art

As a prototype selected electroactivator

[Certificate for utility model 18705, publ. 07/10/01], having a housing, two bases made of an insulating material and between which there is a central cylindrical graphite anode and a steel cathode coaxial with respect to it. A working chamber is formed between the cathode and the anode, which is divided by the cylindrical diaphragm from the belting fabric into the anode and cathode chambers. In the lower part of the anode there is a cavity for receiving a working reagent - sodium chloride solution. The cavity is connected by radial channels to the anode chamber, which, in turn, is connected to the anolyte outlet pipe fixed to the upper base. The cathode chamber is connected to a catholyte outlet pipe, also fixed to the upper base. Through a threaded current lead, which is a copper pin passing through the upper base and screwed into the anode, voltage is applied to the anode. Voltage is applied to the cathode through a terminal on its outer surface.

The main disadvantage of the prototype is the following. During operation, the copper pin undergoes electrochemical corrosion and is destroyed. The introduction of copper ions into the body relative to the porous graphite anode leads to its failure. In this case, the affected area is relatively small, but leads to exit out of order of the entire anode and it is required to replace the entire positive electrode.

Utility Model Disclosure

The utility model is based on the task of increasing the maintainability of the device, namely, the creation of a device, in which case the failure of the anode does not require replacement of the entire positive electrode.

A device for producing electroactivated solutions includes two bases, between which an axial cylindrical anode is placed, to which a cathode is mounted coaxially. A working chamber is formed between the cathode and the anode, which is divided into a cathode chamber and anode chamber by a semipermeable membrane coaxial with respect to them. A nozzle for supplying a working reagent is fixed on one of the bases, an axial cavity is made in the anode, communicating with a nozzle for supplying a working reagent. The axial cavity is also connected by channels to the anode chamber. The anode chamber communicates with the anolyte branch pipe, the cathode chamber communicates with the catholyte branch pipe. The device is also equipped with a threaded current lead that connects the anode to the base. New, distinguishing the device from the prototype, is that the anode is made integral in height with different parts. Said threaded current lead is connected to a base to which a smaller part of the anode is adjacent.

The threaded current lead is also designed to secure the anode to the base. The cathode can be connected to the base by creating a tight contact of its inner surface with the side surface of the base.

Utility Model Embodiment

In more detail, the essence of the utility model is disclosed in the following implementation example and illustrated in FIG. 1, which shows a longitudinal section of the device and Figure 2 is a fragment of the connection.

A utility model is disclosed using an example of a vertically oriented device. In this case, conditionally one of the bases is selected as the upper base 1, the other as the lower base 2. Both bases are made of insulating structural material. A cylindrical anode 3 is mounted between the bases along their axis, for example, made of graphite or graphite-based composite material. Coaxial to the anode 3, a metal cathode 4 is installed, which is a cylindrical shell with flanges. A working chamber is formed between the anode 3 and the cathode 4, which is divided by a semipermeable membrane 5 into the anode chamber 6 and the cathode chamber 7. The semipermeable membrane is mounted coaxially to the electrodes and can be made of any material suitable for this purpose. The anode chamber 6 communicates with the anolyte outlet pipe 8 using the channel 9 made in the anode 3 and the channel 10 communicating with it made in the upper base 1. The cathode chamber 7 communicates with the catholyte outlet pipe 11 using the channels 12 made in the upper base 1. The anode 3 is made integral and has two different-sized parts mounted one on top of the other, i.e. the anode is composite in height. In the considered example, with the conditional choice of the upper and lower bases, the greater part 13 of the anode is adjacent to the upper base, the smaller part 14 of the anode is adjacent to the lower base. Parts of the anode are tightly adjacent to each other, forming a single electrode, and mate, for example, on conical surfaces. A pipe 15 for supplying a working reagent is attached to the lower base, which is connected through the channel 16 at the base to an axial cavity 17 made in a smaller (lower) part of the anode. The axial cavity 17 of the radial channels 18 communicates with the anode chamber 6.

The cathode 4 is connected to the lower base 2, for example, by means of bolts 19 (or other connections) connecting the flanges of these elements. The cathode 4 can be connected to the upper base by means of a tight connection (tight fit) of the upper part of its inner surface and the side surface of the upper base. To do this, in the upper part of the cathode, its inner surface is made conically tapering to the bottom. The current supply of the cathode is terminal 20, mounted on its outer surface.

The anode with its smaller lower part 14 is connected to the lower base 2 by means of a conductive pin 21, which serves as the current supply of the anode. Instead of a stud 12, a bolt can be used as a current lead and a fastener. The upper part of the anode is fixed by the shoulder of the upper base.

The device operates as follows.

Any electrically conductive liquids, for example, solutions of NaCl, KaCl, water from salt sources, including sea water, etc., can be used as a working reagent for producing electroactivated solutions.

The working reagent through the pipe 15, the cavity 17 and the channels 18 enters the working chamber. Under the influence of an electric field, the solution is electroactivated and separated by a semipermeable membrane into two streams - one to the cathode, the other to the anode. In this case, anolyte (a solution having acidic properties) is formed in the anode chamber, and catholyte (a solution having alkaline properties) is formed in the cathode. The catholyte and anolyte for the corresponding branch pipes enter the collectors and are used for their intended purpose. During operation, the conductive pin 21 undergoes electrochemical corrosion and collapses, destroying the anode, namely, its smaller lower part. At the same time, to restore the operability of the device, it is not necessary to replace the entire electrode; it is enough to replace the smaller part of the anode, which is no more than 30% of its total mass. Thus, with an 8-hour working day, approximately once a year, the removable part of the anode must be replaced, and the service life of the anode as a whole is practically unlimited.

The connection of the cathode with the upper base simplifies the assembly of the structure.

The utility model can be used in various sectors of the national economy for the preparation of disinfectant, washing and sterilizing solutions. The resulting solutions can also be used for processing food products (vegetables, fruits, meat) in order to increase their shelf life, in the production of electroactivated solutions (catholyte and anolyte) for disinfection, washing, for sterilization in medicine, in the food industry, in public utilities during wastewater disinfection, during washing, disinfection with an aerosol, during disinfection in drinking water supply systems, in agriculture and veterinary medicine, in housing and communal services, etc. .

Claims

USEFUL MODEL FORMULA

1. A device for producing electroactivated solutions, including two bases, between which an axial cylindrical anode is placed, a cathode is coaxially mounted between the cathode and the anode, a working chamber is formed, which is divided by a coaxial semipermeable membrane into the cathode chamber and the anode chamber, a pipe is fixed on one of the bases supply of the working reagent, in the anode an axial cavity is made, communicating with the pipe for supplying the working reagent, and also connected by channels to the anode chamber, which together they are connected with the anolyte outlet pipe, the cathode chamber is in communication with the catholyte outlet pipe, the device is also equipped with a threaded current lead of the anode, characterized in that the anode is made integral in height with different parts, said threaded current lead is attached to the base, to which the smaller part of the anode is adjacent and is intended also to fix the anode on the base.

2. The device according to p. 1, characterized in that the cathode is connected to the base by creating a tight contact of its inner surface with the side surface of the base.

1U

FIG. 1 FIG. 2

SUBSTITUTE SHEET (RULE 26)