RU2661548C1 - Device for measuring electrode potentials on metallic surface - Google Patents

Abstract

FIELD: construction; machine building.

SUBSTANCE: invention relates to construction and engineering and can be used to measure electrode potentials, to detect micro- and macroscopic discontinuities in coatings on metals in various products, studying the electrochemical corrosion of dissimilar materials in interaction with the environment, ensuring the corrosion resistance of metals and welded joints. A device for measuring electrode potentials on a metal surface comprises an electrode assembly including a reference electrode (1) of noble metal, which is placed in a flexible tube (2) of dielectric material filled with fibrous fiberglass material (3); holder (4) of the electrode assembly tube; load area (5); load (6); the electrolyte supply adjustment tap (7); a tube (8) for supplying the electrolyte to the microcapillary; electrolyte (9); capacity (10) for the electrolyte; a tripod (11); a device (12) for fixing the vessel to the electrolyte; a computer monitor (13); device (14) for vertical movement of the electrode assembly; a video camera (15); millivoltmeter (16); table (17); coordinate table (18); micrometric limbs (19) and (20) for moving the table; an insulating spacer (21); the test sample (22).

EFFECT: invention provides the possibility of local measurement of electrode potentials on metal surfaces with structural and chemical heterogeneity in small areas and individual structural components of the material.

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Description

The present invention relates to construction and mechanical engineering and can be used to measure electrode potentials, detect micro- and macroscopic discontinuities in coatings on metals in various products, study the electrochemical corrosion of dissimilar materials when interacting with the environment, and ensure the corrosion resistance of metals and welded joints.

From the prior art, devices for measuring electrode potentials are known, which are electrolytic cells with a standard hydrogen or calomel electrode. Devices are also known for providing a portioned supply of a drop of electrolyte to a metal surface and immersion in it a reference electrode of a noble metal. Known electrochemical cells for the study of metal corrosion (ed. Certificate. SU No. 927037, publ. 2000; pat. RU 2085926, publ. 21.07.1997). These devices allow you to determine the average electrode potential of the material. The disadvantage of these technical solutions is that they are not designed to determine electrode potentials on curved surfaces and on small areas of metal in contact with an aggressive environment.

Closest to the claimed device in technical essence is an electrochemical cell for the study of metal corrosion, consisting of a table, capillary, electrolytic key, a vessel with a working solution, a reference electrode, a movable table, insulating gaskets, millivoltmeter (US Pat. RU No. 2088913, publ. 27.08 .1997).

The disadvantages of this technical solution are the low accuracy of the measurement of electrode potentials, the difficulty of regulating the measurement process, especially on curved surfaces due to drainage of the electrolyte, the dependence of the state of the surface moistened with a drop of electrolyte on the measurement results, therefore, the known device can determine the average electrode potential of the metal surface sections only over a large area of at least 10 mm ² .

The technical problem to which the invention is directed is the creation of a device of increased accuracy for local measurement of electrode potentials of metal surfaces with structural and chemical heterogeneity. Locality of the measurement is achieved by limiting the spreading of the electrolyte on the test surface and the use of an electrode of small diameter 0.05-1.2 mm, which makes it possible to limit the spreading of the measured galvanic current to an area close to the cross-sectional area of the reference electrode.

This device for measuring electrode potentials on a metal surface, like the closest analogue, contains an electrode assembly, an electrolyte supply system to the measurement zone, a coordinate table, a millivoltmeter. The above technical problem is solved due to the fact that the claimed invention differs from the closest analogue in that the electrode assembly is made in the form of a hollow tube of dielectric material with an inner diameter of up to 4 mm, inside which is placed a reference electrode with a diameter of 0.05-1.2 mm of noble metal connected to a millivoltmeter, and the end of the electrode does not reach a distance of no more than 3 mm to the end of the tube, and the space between the walls of the inner surface of the tube and the outer surface of the electrode is filled fibrous material through which the electrolyte is fed through a flexible tube from the tank to the measurement zone. The fibrous material is placed in the cavity of the tube and extends beyond the end of the tube by 0.3-1.5 mm, and the end of the reference electrode is located above the end of the tube by 0.5-3 mm. The millivoltmeter is designed to measure the voltage between the reference electrode and the sample.

The technical result from the use of the invention is to provide increased accuracy and locality of the measurement of electrode potentials on metal surfaces with structural and chemical heterogeneity in small areas and individual structural components of the material. The measurement of electrode potentials in small areas by metal surface area is necessary, in particular, when assessing the corrosion resistance of welded joints from steels, non-ferrous metals and alloys, as well as when assessing the corrosion resistance of two-phase materials, for example ferritic-pearlitic steels.

In the proposed device, the noted drawbacks of existing devices and the achievement of the above technical result is achieved due to the fact that instead of the electrode cell with a free-lying drop of electrolyte on the metal surface, an electrode cell is used, created by a reference electrode with a diameter of 0.05-1.2 mm, located inside the capillary fibrous material placed in the housing of the electrode assembly.

The electrolyte is supplied through a tube. Electrolyte spreading is limited by the area of contact of the fibrous material on the surface of the sample, which ensures the measurement of the electrode potential in small areas, commensurate with the size of the structural components of metallic materials.

For a short period of time necessary to measure the value of the electrode potential, the electrolyte does not spread over the surface of the sample, limited by the area of the inner diameter of the polymer tube, pressed by the load to the sample.

The area of measurement of the electrode potential is determined by the area of the end face of the reference electrode at the point of contact with the test surface of the sample.

The locality of the measurement is ensured by the use of a small-diameter electrode with a pointed end comparable in size to the inhomogeneities of the surfaces of the sample section under investigation.

In the particular case of the invention, to ensure the stability of the measurement results at different points of the test sample on the electrode assembly body, a platform is provided for securing the load, creating a constant force sufficient to press the end of the fibrous filler to the sample, not depending on the movement of the device on the surface of the test sample.

In addition, in the particular case of the invention, to ensure the accuracy of installation of the electrode assembly on the test surface of the sample and to observe the measurement process on an enlarged scale x (10-24) on the display screen, the device can be equipped with a video camera connected to a computer.

The invention is illustrated in the drawing, which shows a General diagram of a device for measuring electrode potentials.

The invention is illustrated in the drawing, which shows:

1 - reference electrode made of noble metal (gold, platinum);

2 - a tube made of a dielectric material (polyethylene, polystyrene or polymethyl acrylate);

3 - fibrous material;

4 - holder of the electrode assembly;

5 - platform for cargo;

6 - cargo;

7 - crane;

8 - a flexible tube for supplying electrolyte to the microcapillary;

9 - electrolyte;

10 - capacity for electrolyte;

11 - tripod;

12 - device for mounting containers with electrolyte;

13 - computer monitor;

14 - a device for vertical movement of the electrode assembly;

15 - video camera;

16 - millivoltmeter;

17 - table;

18 - coordinate table;

19, 20 - micrometric limbs;

21 - an insulating gasket;

22 - test sample;

h is the gap between the reference electrode and the surface of the sample.

A device for measuring electrode potentials on metal surfaces with geometric, structural and chemical heterogeneity comprises: an electrode assembly comprising a reference electrode 1 of a noble metal (gold or platinum), which is placed in a flexible tube 2 of a dielectric material (polyethylene, polystyrene or polymethylacrylate), filled with fibrous material 3, providing a capillary effect when supplying electrolyte from the electrolyte supply system to the measurement zone.

The device also comprises a holder 4 of the tube of the electrode assembly and a platform 5 for cargo 6 fixed to the tube 2. The crane 7 and a flexible tube 8 for supplying the electrolyte 9 through the fibrous material 3 to the test sample are included in the electrolyte supply system into the measurement zone, as well as a container 10 for electrolyte.

A device for measuring electrode potentials comprises a tripod 11, to which a holder 4 of the tube of the electrode assembly and a capacitance 10 for the electrolyte are attached, fixed by means of the device 12 for attaching it to the tripod 11.

A device 14 for vertical movement of the electrode assembly and a video camera 15 connected to a computer monitor 13 are also mounted on a tripod 11. The measurement of electrode potentials is carried out by means of a millivoltmeter 16.

The device also includes a table 17, on which a tripod 11 and a coordinate table 18 are mounted to accommodate the test sample. The coordinate table 18 is equipped with micrometric limbs 19 and 20 for moving the table along the guides installed on the table 17; an insulating gasket 21, mounted on the surface of the coordinate table and intended for installation on it of the investigated metal sample 22.

The device is used as follows. The studied metal sample 22 through an insulating strip 21 is placed on the coordinate table 18 and connected to the contact wire of the millivoltmeter 16. In the holder 4, a tube 2 of dielectric material is fixed, filled inside with a known fibrous material 3, for example, fiberglass. Inside the fibrous material 3, capable of passing liquid through itself, there is a reference electrode 1 made of a noble metal, mainly gold or platinum, and the pointed end of the reference electrode 1 does not reach the end of the tube 2 at a distance h = 0.5-3.0 mm, which avoids short circuits in the measuring electrical circuit. The holder 4 of the electrode assembly is connected to a tripod 11 and to a device 14 providing vertical movement of the electrode assembly. The position of the sample 22 relative to the electrode assembly is set manually using micrometric dials 19 and 20, or automatically by stepping motors of the coordinate table (not shown).

The electrode assembly is brought to the sample 22 and the load 5 is loaded platform 5 to ensure a constant and sufficient pressure of the load. The reference electrode 1 by means of a device 14 for vertical movement of the electrode assembly is moved to the surface of the sample 22 and is fixed at a distance h = 0.5 mm from the point of contact of the electrolyte with the sample. From the electrolyte container 10 through the tube 8 through the valve 7, the electrolyte 9 through the fibrous material 3, placed in the flexible tube 2, enters the contact zone of the reference electrode 1 with the test sample 22. Measurement of the electrode potential between the contact point on the test sample 22 and the reference electrode 1 produced by millivoltmeter 16. The video camera 15 fixes the position of the electrode assembly and its movement along the marks on the test sample, and in real time the magnitude of the electrode potentials is recorded in digital milli 16. The apparatus oltmetrom fixes values of electrode potentials not only locally, but also continuously by moving the sample on the coordinate table micrometer limbs 19 and 20.

In computer processing, the measurement results are combined at time points for recording the coordinates of the measurement sites and the corresponding values of the electrode potentials at the measurement points.

A digital millivoltmeter with memory, a video camera and a computer automatically record the values of electrode potentials and present the measurement results on paper or other media, with the possibility of obtaining research results in real time.

Example 1. Local measurement of electrode potentials of structural components of dissimilar materials, for example, zinc-filled coatings containing aluminum.

Example 2. The measured values of the electrode potentials of a welded joint made of galvanized steel with a metal-filled coating of the seam and the heat-affected zone. The measurement results make it possible to evaluate the nature of corrosion damage and to predict the corrosion behavior of welded joints of galvanized steel in aggressive environments. This information can be used in the development of welding processes.

The invention can be used to determine electrode potentials on the surfaces of metallic materials having electrochemical heterogeneity, and to solve various production and scientific problems:

- assessment of corrosion resistance of materials;

- assessment of the electrochemical heterogeneity of the structural constituent materials;

- prediction of the service life of metal structures;

- development of new metal corrosion-resistant materials;

- design of welding and soldering technology for materials providing corrosion resistance of joints;

- design of welding and soldering technology for dissimilar materials;

- design of welding and brazing technology for steels with metal anticorrosive coatings, ensuring minimal damage and preservation of the protective coating;

- detection of micro- and macroscopic discontinuities in coatings on metals;

- determination of corrosion properties on products that were in use to predict residual life.

Claims (2)

1. A device for measuring electrode potentials on a metal surface, containing an electrode assembly connected to an electrolyte supply system in the measurement zone, a coordinate table with a dielectric surface for installing the test sample, a millivoltmeter connected to the electrode assembly and configured to connect to the test sample, characterized the fact that the electrode assembly is made in the form of a hollow flexible tube of dielectric material with an inner diameter of 0.8-4 mm, inside of which an electrode is placed of a noble metal with a diameter of 0.05-1.2 mm, connected to a millivoltmeter, while the end of the electrode is located inside the tube at a distance of 0.5-3.0 mm to the end of the hollow flexible tube, and the annular space between the electrode and the inner wall is hollow flexible the tube is filled with fibrous material. 2. The device according to claim 1, characterized in that a platform for securing the load is made on the body of the electrode assembly.

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