RU106376U1 - CELL FOR RESEARCH OF ELECTROCHEMICAL PROCESSES - Google Patents

Abstract

 1. A cell for the study of electrochemical processes, containing a dielectric housing filled with the fluid being studied, with a working electrode, an auxiliary electrode and a reference electrode fixed therein, wherein the dielectric body is made of cylinder, cover and base fastened together, characterized in that it communicated with the pipeline in which the studied fluid flows through the fluid inlet made at the base of the fluid inlet and the fluid outlet, the reference electrode is silver chloride and contains a housing in which a tube with an inner silver rod is placed, a layer of silver chloride deposited on top of the rod, over which a layer of fibrous material is fixed, and the reference electrode housing is filled with an electrolyte solution having the same salinity as the studied fluid in addition, the working and auxiliary electrodes are electrically isolated from each other and are located in the same vertical plane with the reference electrode. ! 2. The cell according to claim 1, characterized in that glass fiber is used as the fibrous material. ! 3. The cell according to claim 1, characterized in that the auxiliary electrode is made of metal that is electrochemically inert to the fluid being studied. ! 4. The cell according to claim 3, characterized in that the auxiliary electrode is made of platinum.

Description

The utility model relates to measuring technique and can be used to study electrochemical processes occurring on the surface of underwater equipment in marine conditions.

The closest analogue of the claimed utility model is a cell for the study of electrochemical processes, containing a dielectric casing filled with the fluid under study, with a working electrode, an auxiliary electrode and a reference electrode fixed in it, while the dielectric casing is made of a cylinder, a cover and a base fixed together ( see patent for invention RU 2326374, G01N 27/28, 10.06.2008).

The disadvantages of the known device are:

- the difference between the electrochemical characteristics of the working electrode when measuring in a known device from the electrochemical characteristics of the material of an underwater structure in a moving fluid (sea water), since studies in the known device are carried out under conditions different from those in which the underwater structure is located (aeration, humidity, temperature) ;

- insufficiently high accuracy in determining the current-voltage characteristics of the working electrode in the studied fluids;

- the complexity and time required for assembly-disassembling operations and preparing the cell for repeated measurements.

The objective of the claimed utility model is to create a universal cell for the study of electrochemical processes without the above disadvantages.

The claimed utility model ensures the achievement of the following technical results:

- improving the accuracy of studies of electrochemical processes, due to the approximation of laboratory conditions for research of electrochemical processes to the real conditions in which the underwater structure is located;

- reducing the complexity and time spent in preparing the cell for measurements, due to the absence of the need for assembly - disassembly of the cell during repeated measurements;

- improving the accuracy of determining the current-voltage characteristics of the working electrode in the studied fluids;

- increase the life of the reference electrode.

The technical result of the claimed invention is achieved due to the fact that the cell for the study of electrochemical processes contains a dielectric housing filled with the studied fluid, with a working electrode fixed therein, an auxiliary electrode and a reference electrode, while the dielectric body is made of cylinder, cover and of the base, and also due to the fact that the cell is in communication with the pipeline in which the studied fluid flows through the inputs made in the base a hole for the fluid and the outlet for the fluid, the reference electrode is silver chloride and contains a housing in which a tube with an inner silver rod is placed, a layer of silver chloride deposited on top of the rod, over which a layer of fibrous material is fixed, and the reference electrode housing is filled with a solution electrolyte having the same salinity as the fluid under study, in addition, the working and auxiliary electrodes are electrically isolated from each other and are located in one vert cial plane with the reference electrode.

Glass fiber may be used as the fibrous material.

The auxiliary electrode can be made of a metal that is electrochemically inert to the fluid being studied, for example, platinum.

The communication of the cell with the pipeline in which the test fluid flows through the fluid inlet and the fluid outlet, makes it possible to conduct research in a moving fluid, i.e. under conditions close to the conditions in which the underwater structure is located, and also excludes assembly-disassembling operations of the cell during repeated measurements due to the fact that the studied fluid passes through the cell flowing, and therefore there is no need to disassemble the cell to fill it with the test fluid before repeated studies.

The electrical isolation of the working and auxiliary electrodes from each other and their location in the same vertical plane with the reference electrode improves the accuracy of determining the current-voltage characteristics of the working electrode in the studied fluids by creating the most uniform electric field in the electrolyte and minimizing the influence of electrical noise arising in the studied fluid environment, on the measurement results of the current-voltage characteristics of the working electrode.

Filling the housing of the reference electrode with a solution having the same salinity as the fluid under study provides an increase in the accuracy of determining the current-voltage characteristics of the working electrode in the studied solutions by minimizing the influence of environmental properties on the chemical composition of the electrolyte in the reference electrode and minimizing errors in determining the potential of the working electrode reference electrode associated with the concentration transfer of chloride ions from the electrolyte solution in the reference electrode to the study fluid in the cell body.

The silver chloride electrode used as a reference electrode has a stable potential and simple construction.

Placing a layer of fibrous material, such as glass wool, on top of the silver chloride layer on the silver electrode fixes the silver chloride layer on the silver rod and increases the life of the reference electrode by preventing silver chloride from shedding from the silver rod.

The advantage of making an auxiliary electrode from an metal that is electrochemically inert to the fluid under investigation, for example, from platinum, is that platinum is ideally polarizable, i.e. its potential can be changed in a wide range (usually several volts) and, in addition, platinum does not oxidize in aqueous media at any pH and provides high electronic conductivity.

The essence of the utility model is illustrated by drawings.

Figure 1 presents a General view of the cell for the study of electrochemical processes.

Figure 2 presents a top view of the cell for the study of electrochemical processes.

Figure 3 presents a portion of the reference electrode fixed in the lid.

The cell for the study of electrochemical processes contains a dielectric housing made of a cylinder 1, a cover 2 and a base 3 fastened together, and also contains a reference electrode 4 fixed in the cover 2, a working electrode 5 with an insulated wire 6 brought out through the side hole 7 of the cylinder 1, an auxiliary electrode 8 with an insulated wire 9 brought out through the side hole 10 of the cylinder 1, and a dielectric cylindrical element 11.

The dielectric cylindrical element 11 is installed inside the cylinder 1 coaxially with it and has a height less than the height of the cylinder 1.

The dielectric housing is filled with the investigated fluid 12.

On the surface of the base 3, located between the cylinder 1 and the dielectric cylindrical element 11, holes 13 are made in which the working electrode 5 and the auxiliary electrode 8 are rigidly fixed. The working electrode 5 and the auxiliary electrode 8 are located in the same vertical plane with the reference electrode 4. The distance between the working electrode 5 and the auxiliary electrode 8 is about 20 mm

The auxiliary electrode 8 may protrude from the outer surface of the base 3 by no more than 1 mm, and the working electrode 5 is flush with the outer surface of the base 3.

The reference electrode 4 is rigidly fixed in the center of the cover 2. Inside the housing 20 of the reference electrode 4 there is a tube 14 with an inner silver rod 15. The housing 20 of the reference electrode 4 is filled with an electrolyte solution 16, which is a solution of sodium chloride (NaCl), which also has a salinity of test fluid. An insulated wire 17 is removed from the reference electrode 4.

A silver chloride (AgCl) 18 layer was deposited on a silver rod 15 by an electrochemical method to create a second-kind electrode reversible by anion. A layer of fibrous material 19 is fixed over the layer of silver chloride 18, which fixes the layer of silver chloride 18 on the silver rod 15. The tight adherence of the layer of fibrous material 19 to the layer of silver chloride 18 prevents it from shedding from the silver rod 15. The tube 14 can be made of polymer, and in as the fibrous material 19, glass wool can be used, fixed with fixing elements (not shown in the drawing) over a layer of silver chloride 18.

The gap between the cylinder 1 and the dielectric cylindrical element 11 is filled with a chemically neutral dielectric sealant 21 to ensure electrical isolation of the working 5 and auxiliary 8 electrodes from each other.

The cell is in communication with a conduit (not shown) in which the test fluid flows through the fluid inlet 22 and the fluid outlet 23 made in the central part of the base 3. The base 3 may have ends of curved shape for the convenience of fixing it to the pipeline. Response holes are made in the pipeline for passage of the fluid under investigation from the pipeline to the cell (not shown in the drawing). In addition, through the above-mentioned pipeline, through openings are made (not shown in the drawing), interfaced with holes 13 in which the working electrode 5 and the auxiliary electrode are fixed 8. The through openings have a diameter equal to or greater than the diameter of the holes 13.

The working electrode 5 can be made of the same metal from which the pipeline is made. The auxiliary electrode 8 may be made of a metal that is electrochemically inert to the fluid being studied, for example, platinum.

The study of electrochemical processes through the claimed cell is as follows.

The properties of the working electrode are investigated by placing a cell on a pipeline with a moving fluid being studied, thus simulating the conditions in which underground equipment is in the marine environment.

The base 3 is fixed on the wall of the pipeline in which the studied fluid moves. To do this, the curved ends of the base 3 with a rubber gasket are tightly pressed to the pipe with clamps so that the base 3 fits snugly against the pipeline.

The base 3 is installed on the pipeline so that the inlet 22 and the outlet 23 are mated with mating holes made in the pipeline (not shown).

The pressure is created in the pipeline and the test fluid 12 is passed through it. The test fluid 12 enters the cell housing through the inlet 22 and fills it. Through the outlet 23, fluid is drawn from the cell.

The study of electrochemical processes is carried out by measuring the current-voltage characteristics of the working electrode 5.

Before the measurements are started, the salt content in the test fluid 12 is measured, after which the reference electrode 4 is filled with electrolyte 16 with the same salt content as the test fluid 12. For filling the electrolyte 16, there is a hole (not shown) in the housing of the reference electrode 4, in which, using a syringe, is poured into an electrolyte solution 16, after which the hole is sealed. The reference electrode 4, the potential of which does not change, serves to pick up the control signal.

The insulated wire 6 of the working electrode 5, the insulated wire 9 of the auxiliary electrode 8 and the insulated wire 17 of the reference electrode 4 are connected to the corresponding three potentiostat sockets (not shown in the drawing).

The contacting of the working electrode 5 and the auxiliary electrode 8 with the studied fluid 12 flowing in the pipeline is ensured by the presence of through openings in the pipeline associated with the openings 13.

Using the potentiostat, the current-voltage characteristics of the working electrode are measured 5. The potential of the working electrode 5 is regulated with respect to the reference electrode 4 using the auxiliary electrode 8. The ohmic component of the measured potential of the working electrode 5 is leveled in modern potentiostats by IR-compensation of the ohmic potential jump.

The magnitude and nature of the change in the polarization (volt-ampere) characteristics of the working electrode 5 make conclusions about the mechanism of electrochemical processes occurring at the interface: a working electrode / moving fluid (electrolyte).

The claimed cell for the study of electrochemical processes allows the study of electrochemical processes in moving fluids in laboratory conditions, close to the conditions in which the surface of the underwater structure in marine conditions and ensures the accuracy of determining the current-voltage characteristics of the working electrode in the studied fluid.

The utility model can be used on test benches in the study of electrochemical processes occurring on the surface of underwater equipment in marine conditions.

Claims (4)

1. A cell for the study of electrochemical processes, containing a dielectric housing filled with the fluid being studied, with a working electrode, an auxiliary electrode and a reference electrode fixed therein, wherein the dielectric body is made of cylinder, cover and base fastened together, characterized in that it communicated with the pipeline in which the studied fluid flows through the fluid inlet made at the base of the fluid inlet and the fluid outlet, the reference electrode is silver chloride and contains a housing in which a tube with an inner silver rod is placed, a layer of silver chloride deposited on top of the rod, over which a layer of fibrous material is fixed, and the reference electrode housing is filled with an electrolyte solution having the same salinity as the studied fluid in addition, the working and auxiliary electrodes are electrically isolated from each other and are located in the same vertical plane with the reference electrode. 2. The cell according to claim 1, characterized in that glass fiber is used as the fibrous material. 3. The cell according to claim 1, characterized in that the auxiliary electrode is made of metal that is electrochemically inert to the fluid being studied. 4. The cell according to claim 3, characterized in that the auxiliary electrode is made of platinum.