RU2454489C1 - Electrochemical cell for treatment of electrolyte solutions - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: according to invention electrochemical cell for treatment of electrolyte solutions, containing located in coaxial tubular electrodes isolated by tubular ceramic partition forming anode and cathode chambers, is provided with additional isolating membrane in upper part of anode chamber, which allows products of anodic treatment to leave the space before anode and prevents penetration of water delivered to the space above membrane. This solution allows to protect materials of collector sleeve, sealants from effect of strong oxidants - products of anodic reaction, as water is supplied via generatrix and moves from inlet to collector sleeve till outlet via spiral absorbing and dissolving bubbles of electrolytic gases and minor quantity of electrolyte which passed isolating membrane.

EFFECT: providing more complete conversion of electrolyte solution, obtaining more products of electrolysis, reducing energy looses.

1 dwg

Description

The invention relates to the field of chemical technology, in particular to devices for the electrolysis of aqueous solutions of electrolytes, and can be used in various electrolysis processes for the production of various chemical products.

Electrochemical or electrolysis treatment of a liquid medium is a widespread technological method. Its practical implementation is carried out using electrochemical (electrolytic, electrolysis) devices of various designs.

A device is known for electrochemical processing of a liquid medium, made in the form of an electrolyzer with flat monopolar electrodes of positive and negative polarity, between which an interelectrode cavity is formed (GB 1526687, G02F 1/46, 1978). In the specified interelectrode cavity of this device, an electrochemical treatment of the liquid medium is carried out to obtain mixed anodic and cathodic electrolysis products, as well as gases released during electrolysis.

A device for unipolar electrochemical processing of a liquid medium is also known, made in the form of a diaphragm electrolyzer with flat monopolar electrodes of positive and negative polarity, between which an ion-permeable separation element is arranged in the form of a flat diaphragm or membrane that separates the interelectrode cavity into the anode and cathode chambers with supply pipes and drainage of liquid medium. In these isolated unipolar electrode chambers, the liquid medium is subjected to a unipolar anodic or cathodic electrochemical treatment to obtain anodic or cathodic electrolysis products, as well as gases released during electrolysis ("Purification of Drinking Water, Synthesis of Washing, Disinfecting and Sterilizing Solutions from Water", fifth edition, M ., 1992, p. 5, 11, Publishing and Publishing Center YaiK).

An electrochemical diaphragm device with flat monopolar electrodes of positive and negative polarity is known, between which an ion-permeable separation element in the form of a flat polymer membrane is placed, separating the interelectrode space into the anode and cathode chambers with nozzles for supplying and discharging a liquid medium, and at least in the anode chamber at least one flat bipolar electrode (US 4248681, C25B 1/22, 1981).

When this device is used, a saturated solution of sodium chloride is subjected to electrochemical treatment, and in the electrode chamber with an anode and one or more bipolar electrodes, a mixture of chlorine with chlorine dioxide is obtained, which is used to disinfect water in the swimming pool.

Also known is a flow-through electrochemical device (flow-through electrolytic cell) used as part of an electrochemical installation for treating water or a water-salt solution. It contains a tubular and rod-shaped cylindrical monopolar electrodes coaxially arranged in a vertical plane, between which an annular interelectrode cavity is formed, separated by an ion-permeable ceramic tube diaphragm into isolated unipolar electrode annular chambers. At the opposite ends of the electrodes, dielectric detachable collector elements with nozzles for supplying and discharging a liquid medium are installed, consisting of a collector sleeve and a collector head, between which facing surfaces are joined together, an annular groove is formed. An elastic sealing ring element is installed in it, in which the end of the ceramic tubular diaphragm is fixed, and the gap between the surfaces of the collector sleeve and the monopolar tubular electrode facing each other is sealed. On the end wall of the collector head there is an annular groove with a sealing ring element, and on the threaded ends of the monopolar rod electrode, which are located outside the collector head, standard fasteners in the form of a nut and washer are installed (US 5628888, C25B 9/00, 1996).

The disadvantage of this flow-through electrochemical device is the complicated design of its detachable collector element in the form of a sleeve coupled to the collector head, as well as the low reliability of sealing the annular gap by means of a manually applied sealant.

The closest prototype of the proposed electrochemical device is an electrochemical device for processing a liquid medium, made in the form of a tubular and rod coaxially arranged monopolar cylindrical electrodes with dielectric collector sleeves fixed at their ends, the inner cavity of which is connected with the annular interelectrode cavity between the surfaces of the monopolar electrodes facing each other, with channels and nozzles for supplying and discharging liquid medium and sealed elas In the annular interelectrode cavity, an ion-permeable diaphragm or membrane separating tubular element and / or at least one bipolar tubular electrode secured by elastic annular elements, the interelectrode annular cavity is divided into communicating or insulated electrode chambers and / or electrolysis cells to obtain unipolar and / or mixed bipolar electrolysis products, the collector bushings are made with a step inside renney surface and pipes for supplying and / or removing the liquid medium are arranged on the side and / or end face of at least one of the collector sleeves (RU 2,130,786, C25B 2/18, C02F 1/46, publ. May 27, 1999).

The disadvantage of this device is the lack of conversion of the electrolyte or other processed solution due to the inefficiency of the ion transport process of the electrolyte substance.

The technical result achieved by using the present invention is to provide a more complete conversion of a solution of sodium chloride or other electrolyte and, accordingly, to obtain more electrolysis products from a smaller area of the electrodes used, with less loss of unreacted electrolyte. Also achieved technical result is the reduction of energy losses due to an increase in the permissible working concentration of the electrolyte.

The specified technical result is achieved in that the electrochemical cell for processing electrolyte solutions, containing coaxially located tubular electrodes located in the housing, the externally located of which is the anode and the internally located is the cathode, and between which is placed a tubular shaped ceramic diaphragm to form the anode and cathode chambers as well as a device for supplying water and saline solution and withdrawing their mixture, is equipped with a separation membrane inserted in the upper part of the anode a second chamber for removing from the cavity in front of the anode the products of the anode treatment and to prevent the penetration of water supplied to the cavity above this membrane.

These signs are significant and interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

Figure 1 is a structural diagram of an electrochemical cell.

According to the present invention, an electrochemical cell device for processing electrolyte solutions is considered, which allows for a more complete conversion of a solution of sodium chloride or other electrolyte and, accordingly, to obtain a greater number of electrolysis products with a smaller area of electrodes used and less loss of unreacted electrolyte.

The device of the electrochemical cell for processing electrolyte solutions contains a housing 1 in which coaxially located tubular electrodes are placed, an externally located tubular electrode 2 is an anode, and a tubular electrode 3, which is a cathode, is located inside it. Between the tubular electrodes is placed a tubular shaped ceramic diaphragm 4, forming the anode 5 and cathode 6 of the chamber by dividing the cavity between the inner and outer placed electrodes into two of these chambers. The separation membrane 7 is inserted in the upper part of the anode chamber 5, which allows the anode treatment products to leave the space in front of the anode and prevents the penetration of water supplied into the space above the membrane. Saline solution from a separate container 8 is fed through an adjustable valve 9. There is also an ejector pump 10 for moving a mixture of water and catholyte into the upper space of the anode chamber between the separation membrane 7 and the upper part of the collector sleeve. The electrodes are connected to a power source through a voltage and current control system. In the case, channels for inlet and outlet pipes for supplying water and a solution of sodium chloride, channel 11 for the withdrawal of anolyte and a mixture of water with saline are organized.

In the present invention, the technical result is achieved in that in a coaxially arranged tubular electrodes, separated by a tubular ceramic diaphragm forming the anode and cathode chambers, an additional membrane is inserted in the upper part of the anode chamber, which allows the anode treatment products to leave the space in front of the anode and prevents the penetration of water supplied into the space above the membrane. This solution allows you to protect the materials of the collector sleeve, seals from the effects of strong oxidizing agents - the products of the anode reaction, since water is supplied along the generatrix and moves from the entrance to the collector sleeve to exit from it in a spiral, capturing and dissolving electrolysis gas bubbles and a small amount of electrolyte passing through the separation membrane. Increasing the resistance to the flow of water flowing over the separation membrane will allow more efficient transfer of ions of the electrolyte substance through the separating ceramic diaphragm, which in turn will reduce the energy consumption of the cell as a whole.

The cell electrodes are made of titanium, and the anode is coated with ruthenium and iridium oxide to protect the anode from dissolution and work as a catalyst for electrolysis processes. The grade of titanium must correspond to the grade of VT1-0 or VT1-00. Ceramic diaphragm is made of alumina and zirconia. The separating membrane is made of chemically resistant materials, such as fluoroplastic, and can have any shape and seal, acting as a nipple. The collector sleeve of the electrolyzer is also made of chemically resistant materials and has at least 3 connecting sockets.

The advantage of this system is, in addition to the above, the obstruction of the cell without liquid inside the anode chamber, since the separation membrane does not have a sealed connection and allows water to penetrate the inside of the anode chamber and prevent the operation of an unfilled cell.

The operation of the cell is ensured by the correct hydraulic connection to the electrolysis system.

The system requires a solution of sodium chloride, tap water and electricity.

Water passes through the internal cavity of the internal electrode (cathode), cooling it, then passing through the input device, which creates a vacuum in the cathode chamber of the cell, pulling the catholyte from the cathode chamber, and the electrolyte solution from the tank comes in its place. The feed rate of the sodium chloride solution is controlled by a control valve, limiting excessive electrolyte consumption. The catholyte, having dissolved in the flowing water, increases its pH, which prepares the water for better dissolution of the products of the anodic reaction in it.

Then the mixture of water and catholyte enters tangentially into the upper space of the anode chamber between the separation membrane and the upper part of the collector sleeve, washing the separation membrane and taking away electrolysis products.

Thus, at the exit from the anode chamber, a solution of anolyte in a mixture of catholyte with water (RASKat) is obtained.

Since the catholyte mainly consists of a solution of sodium hydroxide, and the main components of the anolyte are hypochlorous acid, hypochlorite ion, atomic chlorine, chlorine dioxide, when these solutions are mixed in a large amount of water, the pH of the finished product (RASCat) tends to a neutral value.

The advantage of this scheme

1. Cell cooling during electrolysis.

2. The predominant formation of hypochlorous acid at the anode, which significantly improves the disinfectant properties (RASKat).

3. Maintaining a low pH in the anode chamber, which significantly increases the service life of the anode coating.

EFFECT: invention makes it possible to increase the productivity of electrolysis systems by the degree of conversion of the initial electrolyte in processes related to the production of anode reaction products at the place of their application, such as water treatment and wastewater treatment plants, swimming pools, cooling towers for industrial water recycling cooling systems, oil processing and gas, food industry, medicine, agriculture.

Claims (1)

An electrochemical cell for processing electrolyte solutions, containing coaxially located tubular electrodes placed in a housing, a ceramic diaphragm is placed between the anode and cathode to form the anode and cathode chambers, as well as a device for supplying water and saline solution and withdrawing their mixture, characterized in that it equipped with a separation membrane inserted in the upper part of the anode chamber for removal from the cavity in front of the anode of the products of the anode treatment and to prevent the penetration of water supplied into the cavity above this membrane.