UA124480C2 - The earthing composite anode electrode - Google Patents

Abstract

The invention relates to electrical engineering and technical electrochemistry. Composite electrode of the anode grounding, comprising a structural tubular base made of titanium or its alloy, coated with a chemically stable conductive oxide material consisting of successively applied electrolytic and thermochemical layers of manganese dioxide. The structural tubular base is made of at least two electrically connected coaxial tubes on end-to-end insulating couplings, and the coating of chemically stable conductive oxide material is 10-300 μm. The invention allows the folded electrode to withstand relatively large transverse and longitudinal loads. 2

Description

The invention belongs to electrical engineering and technical electrochemistry, namely to the field of electrochemical cathodic corrosion protection of metal structures and communications in contact with the electrolytic medium, in particular to anode grounding devices, and can be used in anode grounding devices.

The known device is an anode grounding device containing an anode made in the form of a cylinder of titanium alloy, coated with manganese dioxide on the outside and inside, and connected to a tubular bimetallic current collector (Patent of the Russian Federation Mo 2542867 C2 dated 11.06.2013, application Mo 2013126681/02 dated 11.06.2013, Bull. Mo 6 dated 27.02.2015).

The known device does not adequately protect the tubular bimetallic conductor from the harmful effects of oxidizing agents, in particular, the device is particularly vulnerable to the destructive effects of oxidizing agents at the welding points of its elements, since the welding points are constantly in contact with oxidizing agents, from which they are not protected in any way.

The closest in terms of its essential features to the claimed device is the well-known compound electrode of the anode grounding device, which is made in the form of a rod covered with manganese dioxide and connected to a conductive cable (Patent of Ukraine for a utility model Mo 106462 and dated 25.04. 2016, application Mo and 201510781 dated 05.11.2015, Bull. Mo 8).

The disadvantage of the known device is its relatively complex design, which requires for its manufacture a relatively large amount of construction materials and the use of special devices for mechanical, electrochemical and plasma-chemical processing of these materials.

From the practice of industrial use of anode grounding devices in electrochemical protection systems, it is known that the most frequent causes of breakdowns of composite electrodes of anode grounding devices are electrochemical destruction of the electrical contact connection zone, and the presence of a single electrical contact connection with a conductive cable in a known device does not protect against accidental connection of the device from the electrical power source, in case of destruction of this single contact connection, which, in particular, is possible due to the fixation of the contact connection in the known device with soldering, which is vulnerable to the harmful effects of oxidizing agents.

In addition, soldering is a relatively time-consuming process, and its fixation of electrical

The contact connection requires the use of solder, including lead and flux, which contains acid or alkali, which are harmful to health. Also, the residual layer of flux that can remain at the place of soldering has destructive properties for the soldering material, which, accordingly, can lead to the destruction of the electrical contact connection.

A significant drawback of the known device is also the fact that the sealant present in it, enveloping the electrical contact connection, is constantly subject to destruction by the action of a corrosive-active environment and anodic reaction products (oxygen, chlorine). In addition, filling the cavity of the folded electrode with sealant requires a relatively large amount of it (sealant).

The basis of the claimed invention is the task of creating a composite anode grounding device, which would not have the listed disadvantages.

The task is solved by the technical development of a composite anode grounding device, the essence of which is explained by the schematic images in figures 1-4.

The assembled electrode of the anode grounding device, which is internally connected by an electrical contact connection (1) to the conductor of the conductive cable (2) and contains a structural tubular base (3) made of titanium or its alloy, covered with a chemically resistant conductive oxide material (4), and consists of consecutively applied - electrolytic (5) and thermochemical (b) layers (in an enlarged view, the footnotes in Fig. 1 are shown in the oval) of manganese dioxide, according to the claimed technical solution, it differs in that the structural tubular base is made of at least two, electrically connected, coaxial pipes (7, 14) on the end power insulating couplings (8), and the coating of chemically resistant conductive oxide material is 10-300 microns. Additionally, the folded electrode can be dedentately located in a cylindrical metal case (9) or in a perforated dielectric (10), and the location of the folded electrode in the metal case can be sealed with carbon filling (11).

The folded electrode of the anode grounding device can also be connected to the conductor of the current-carrying cable by one, two or more electrical contact connections, which can be located in the cavity of at least one coaxial pipe (12).

The electrical contact connection can be fixed by compressing the walls (13) of the inner coaxial tube (14) around the conductive cable conductor, and can be (516) sealed.

The cavity of the internal coaxial pipe (15) can also be sealed.

Also, the electrical contact connection can be located in the end power insulating coupling, where the cavity (16) between the inner walls of the end power insulating coupling (17) and the inner coaxial pipe is sealed.

At the same time, the cavity (18) between the coaxial tubes can be sealed with a conductive material, such as a conductive backfill made of carbon fines, metal shavings, etc. Also, this cavity can be sealed with conductive polymer paste or any other conductive substance.

Additionally, the folded electrode of the anode grounding device can contain a bend compensator (19) of the current-carrying cable.

The use of an anodic grounding device in a composite electrode of a structure made of electrically connected coaxial pipes on end power insulating couplings allows the composite electrode to withstand relatively greater transverse and longitudinal loads that occur during its installation and operation, and ensures a coating of chemically resistant conductive oxide material from possible its deformations.

Additionally, end power insulating couplings can be used for mechanical attachment of the folded electrode of the anode grounding device to the object of protection (20).

Coaxial pipes are connected to each other by welding them in an inert gas environment, which provides a reliable mechanical and electrical connection.

The presence of two electrical contact connections in the design of the device, respectively, ensures double the reliability of the electrical connection of the composite anode grounding device with the conductor of the current-carrying cable.

The location of the electrical contact connection in the cavity of the internal coaxial pipe provides significantly greater protection of such a connection from unforced mechanical destruction, from the harmful effects of the electrochemical anodic process, from the corrosive-active environment and from the products of the anodic reaction.

The electrical contact connection with the conductor of the conductive cable, which is provided by the compression of the walls of the inner coaxial pipe around the conductor of the conductive cable, determines the reliability of the electrical contact connection, and makes unnecessary the use of soldering, which is vulnerable to the harmful effects of oxidizing agents.

Thus, the claimed invention uses multi-level protection of the electrical contact connection from electrochemical destruction.

The fact that the electrical contact connection with the conductor of the current-carrying cable in the cavity of the inner coaxial pipe is sealed provides the first (minimum) level of its electrical and chemical insulation.

The location of the electrical contact connection with the conductor of the conductive cable in the cavity of the inner coaxial pipe in the end power insulating coupling protects it from mechanical loads. The sealant, which fills the cavity between the inner walls of the end power insulating coupling and the inner coaxial pipe, prevents the penetration of oxidizers to the electrical contact connection, and provides the second level of its electrochemical and chemical protection. In addition, the end power insulating coupling performs the function of an insulator, and provides the third (maximum for this design) level of electrochemical and chemical protection of the electrical contact connection.

Sealing the cavity between the coaxial pipes of the assembled grounding electrode with a conductive backfill reduces its longitudinal electrical resistance and equalizes the current density that flows from its surface during operation, which significantly extends the service life of the device.

The presence of an anodic earthing device in the folded electrode of the bend compensator prevents damage to the current-conducting cable under conditions of cyclic transverse loads.

Placing the composite electrode in a hollow perforated dielectric cylindrical body allows the composite electrode of the anode grounder to be used in the electrochemical protection systems of river and marine structures.

The location and sealing of the composite electrode with carbon filling in the metal cylindrical body leads to a decrease in the transient electrical resistance of the composite electrode of the anode grounding device, and thus extends its service life.

To use the device for its intended purpose (see Fig. 4), the assembled electrode of the anode grounder is placed in a water, soil or any other electrolytic environment where there are objects of protection - metal engineering structures or metal communications, after which the device is connected in the electrical circuit of the cathodic protection station (SCZ) (21) to create the protective potential defined by regulatory documents.

The set of essential features of the compound electrode of the anode grounding device ensures the achievement of a technical result, which is expressed in its relatively longer and relatively more reliable operation, which is provided by its mechanical design and electrical contact connections with the conductor of the conductive cable, which, in particular, is achieved by the use of power insulating couplings and triple insulation of the electrical contact connection.

The specified technical result provides the possibility of relatively wider application of the device in various electrolytic environments.

Drawing figures:

Fig. 1. Schematic representation of the assembled electrode of the anode grounding device.

Fig. 2. Schematic representation of the assembled electrode of the anode grounding device, dedentately located in a hollow perforated dielectric cylindrical body.

Fig. 3. Schematic representation of the composite electrode of the anode grounding device, located in a hollow metal cylindrical body.

Fig. 4. Schematic representation of the application of the composite electrode of the anode grounder in its working position. 1 - electrical contact connection; 2 - conductor of the current-carrying cable; C - tubular base; 4 - coating made of oxide material; 5 - electrolytic layer; 6 - thermochemical layer; 7 - external coaxial pipe; 8 - coupling; 9 - metal case; 10 - perforated dielectric case; 11 - carbon backfill; 12 - the cavity of the coaxial pipe; 13 - walls of the internal coaxial pipe; 14 - internal coaxial pipe; 15 - sealed cavity of the internal coaxial pipe; 16 - the cavity between the inner walls of the end power insulating coupling and the inner coaxial pipe; 17 - the inner wall of the end power insulating coupling; 18 - cavity between coaxial pipes; 19 - bend compensator of the conductive cable; 20 - object of protection; 21 - SKZ.

Within one year, six assembled anode grounding devices by technical decision that

It is claimed that they were used in the anodic field of electrochemical protection (they were installed in several areas of the location of protection objects) JSC Ivano-Frankivskgaz, Kalusky UEGG, p.

Golyny, where during its continuous operation, it ensured the level of protective potential defined by regulatory documents, without any complications in its work.

In addition, in compliance with the regulatory protective potential on the protection objects, the applied voltage decreased from 16V to 5V, and the anode current increased from ЗА to бА according to the indicators of the monitoring devices at the output terminals of the cathodic protection station, which led to the saving of electrical energy of the SCZ.

A composite anode grounder can be manufactured at any machine-building enterprise, using standard materials, mechanisms and devices.

The assembled anode grounding device can be used in production, where there is a need for electrochemical protection of objects in contact with the electrolytic environment.

Claims (10)

FORMULA OF THE INVENTION 1. The composite electrode of the anode grounding device, which is internally connected by an electrical contact connection with the conductor of the current-conducting cable and contains a structural tubular base, which is made of titanium or its alloy, covered with a chemically resistant conductive oxide material, and consists of sequentially applied electrolytic and thermochemical layers of manganese dioxide, which is distinguished by the fact that the structural tubular base is made of at least two, electrically connected, coaxial pipes on end power insulating couplings, and the coating is made of chemically resistant conductive oxide material with a thickness of 10-300 microns. 2. The folded electrode of the anode grounder according to claim 1, which is characterized by the fact that the additionally folded electrode is centrally located in a metal cylindrical body, where the location of the folded electrode is sealed with carbon filling. 3. The composite electrode of the anode grounder according to claim 1, which is characterized by the fact that the composite electrode is centrally located in a perforated dielectric cylindrical body. 4. Composite anode grounding electrode according to any one of claims 1 or 3, characterized in that at least one electrical contact connection is located in the cavity of at least one internal coaxial tube. 5. Composite electrode of an anode grounding device according to any one of claims 1 or 4, characterized in that the electrical contact connection is fixed by compressing the walls of the inner coaxial tube around the conductor of the current-carrying cable. 6. The composite electrode of the anode grounder according to any of claims 1-5, which is characterized in that the electrical contact connection is sealed. 7. Composite electrode of an anode grounder according to any of claims 1-6, which is characterized by the fact that the cavity of the inner coaxial tube is sealed. 8. The composite electrode of the anode grounding device according to any one of claims 1-7, which is characterized in that the electrical contact connection is located in the end power insulating coupling, where the cavity between the inner walls of the end power isolating coupling and the inner coaxial pipe is sealed. 9. Composite electrode of an anode grounder according to any of claims 1-8, which is characterized by the fact that the cavity between the coaxial pipes is sealed with a conductive material. 10. The composite electrode of the anode grounding device according to any one of claims 1-9, which is characterized by the fact that it additionally contains a compensator for bending the current-carrying cable.