SU938106A1 - Cell for corrosive and electrochemical testing of metals under load - Google Patents

Description

one

The invention relates to an electrochemist, in particular to the study of metals under stress at high temperatures and pressures in order to detect the tendency of metals to stress corrosion cracking.

A well-known cell for studying the process of corrosion cracking at high temperatures in an aggressive environment, such as an autoclave, in which a loaded metal working electrode and a reference electrode 11p are placed:

The closest to the invention in its technical essence and the achieved result is a cell for corrosion-electrochemical studies of metals, under load, comprising a housing filled with a corrosive medium, a housing cover fixed on the Kqpnyca lid auxiliary electrode and a reference electrode in a tick-like cylindrical working electrode with a narrowed, central part and a thread on its end sections, a conical sealing sleeve installed between the lower end section the working electrode and the housing, and a device for pressing the coupling to the working electrode | 2

A disadvantage of the known cell is the low accuracy of electrochemical studies of metals under load in

. autoclave test conditions.

The purpose of the invention is to improve the accuracy of research under autoclave tests.

This goal is achieved by the fact that

J5 in a cell for corrosion-electrochemical studies of metals under load, comprising a casing filled with a corrosion test, a casing cover secured to

Claims (1)

2U housing cover auxiliary electrode and the reference electrode, vertically located cylindrical working electrode with a narrowed central part and a thread on its end sections. 3 & A conical sealing sleeve that is installed between the lower section of the working electrode and the housing, and a device to press the coupling to the working electrode, between the end section of the working electrode and its central part, is fitted with a conical coupling, the minimum diameter of which exceeds the diameter of the b-tip. In addition, in order to prevent corrosion on the waterline, a flange is made between the upper end section and the central part of the rybochhch) electrode, and the cell is provided with a cylindrical upper part that is opposed to the flange and has a diameter larger than the flange diameter. Such an embodiment of the cell allows one to provide electrical isolation of the working electrode, a clear limitation of its working surface, and the elimination of the gap effect and corrosion at the waterline. The drawing shows the scheme of the proposed cell. The cell includes a housing 1, a cover 2, an auxiliary electrode 3, a reference electrode 4, a working electrode with a sunken central part S and an external thread on its end sections 6 and 7, flanges 8 and 9, made between the central part 5 and end sections 6 and 7 of the working the electrode, the upper cylindrical Yu and the lower conical 11 couplings, the minimum diameter of which revolves the diameter of the shoulders, and the spring nuts 12 and 13, which serve to press the upper 10 and lower 11 couplings to the sides 8 and 9. The cell operates as follows. Sealing sleeves U and 11 are put on the end sections 6 and 7 of the working electrode, which are wiped into the shoulders 8 and 9 with the help of clamping nuts 12 and 13, then the lower section 6 of the working electrode is screwed into the bottom of the autoclave 14. On the conical sealing sleeve 11 a housing 1 into which a corrosive environment is poured in a CIM in such a way that the upper coupling sleeve 10 is partially immersed in a corrosive environment. Cover the housing 1 with a cover 2 in which the auxiliary electrode 3 and the reference electrode 4 are fixed. Screw the upper portion 1 of the working electrode into the pull 13 64 loading device (not shown). Then install a cover (not shown) of the autoclave, in which current leads (not shown) are installed, providing connection of the auxiliary electrode 3 and reference electrode 4 to the measuring equipment (not shown). After sealing the autoclave 14, it is fixed in the loading device, and the current inlets in the die 2 and the load 15 of the loading device in electrical contact with the upper end section 1C (7 working electrode insulated from the loading device by means of dielectric spacers After that, with the help of a loading device, the required tensile stresses of the working electrode are set, and with the help of 3 measuring equipment, the required level is set. polarization of the working electrode and investigate the electrochemical processes on its surface.When the cell is in operation due to the prevention of gap effects due to reliable sealing of the working electrode with couplings, as well as due to the prevention of corrosion at the waterline due to the exclusion of the contact of the working electrode with the surface of the corrosive medium, the accuracy is greatly increased Electrochemical Research. Formula of the invention 1. Cell d corrosion-electrochemical studies of metals under load, soda storing the corpus filled with the corrosive environment, the body cover, on the caseflash, an auxiliary electrode and a comparison electrode, a vertically located cylindrical working electrode with a narrowed central part and a thread on its end sections, a conical sealing sleeve installed between the lower end of the working electrode and a housing, and a device for pressing the coupling to the working electrode, characterized in that, in order to increase the accuracy of studies under conditions of autoclave x tests, between the lower end section of the working electrode and its central part there is a flange in which the horses are resting