RU2391654C1 - Flow-through ionometre cell - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: flow-through ionometric cell contains solid case with measuring electrode and reference electrode with internal flow-through channel installed in this case. The internal flow-through channel has the first extensive section and the first short inclined section connecting an opening of an inlet tube with the starting point of the first extensive section running along sensing electrode surface of the measuring electrode. The case is made as five-side prism out of polymer material. In cylinder recesses of the prism made on corresponding sides there are the pressure tight attached measuring electrode, the reference electrode and connecting pipes for supply and withdrawal of liquid. They are installed with their symmetry axes in one plane with symmetry axis of the internal flow-through channel. The latter also has the second extensive section running along sensing electrode surface of the reference electrode and the second short inclined section connecting the end of the first extensive section with the starting point of the second extensive section, the end of which is joined with the opening of the tube for withdrawal of liquid. Also the second short inclined section is perpendicular to sensing electrode surface of the reference electrode.

EFFECT: increased reliability of measurement results.

5 cl, 1 dwg

Description

The present invention relates to means for potentiometric determination of the content in solutions of various ions using ion-selective membranes.

It is known to use a three-electrode electrochemical cell [1] with a measuring electrode, an auxiliary electrode, and a reference electrode placed in a background electrolyte solution. A measuring electrode is installed at the end of a glass tube inserted into the cell lid. During the measurements, the oxygen adsorption parameter of the measuring electrode in the background electrolyte solution is determined, then the mobile measuring electrode is transferred and immersed in the studied aqueous medium to adsorb the ions of the controlled substance on its surface, after which it is re-placed in the cell with the background solution and the oxygen adsorption parameter is determined again .

The disadvantage of this device is that it does not provide a continuous determination of the change in the concentration of the analyte in the flow of a controlled fluid, which limits its scope.

For this purpose, flow-through ionometric cells are used, the design features of which are considered in [2].

The ionometric cell [2, p. 234, Fig. 6.5] contains a casing, divided by a partition into two communicating compartments in the lower part of the casing, one of which has a measuring electrode, and the next in the direction of fluid flow - a reference electrode. A tube for supplying fluid connected through a filter to the flow line is inserted into the upper part of the compartment with a measuring electrode, and a tube for draining fluid is installed in the middle of the compartment of the reference electrode. The working surfaces of the electrodes are parallel to each other, but at different distances from the bottom of the housing.

The design features of the cell are associated with the need to equalize the flow rate, the unevenness of which, caused by the operation of the peristaltic pump, distorts the useful signal due to fluctuations in the flow potential.

However, the use of a simple filter does not prevent the possibility of air bubbles entering the body together with the liquid, which settle (“hang”) on the measuring surface of the electrodes, reducing their effective surface, which reduces the sensitivity of the device. Another disadvantage is the significant distance between the electrodes, which leads to an increase in resistance and an increase in the response time of the detector, as a result of which the reliability of the measurement of the device is reduced.

To increase the reliability of measurements in the fluid analysis device [3], a special sample preparation of the analyzed liquid is used with the help of an ion-selective membrane through which the analyzed liquid enters the housing with an internal flow channel formed at the inner surface of the membrane and filled with a carrier fluid (distilled water). When performing measurements, the device is immersed in the analyzed liquid and pumped into the housing using a pump. In this case, as a result of the exchange of ions and molecules through the membrane in the internal flow channel, a liquid sample is formed, which enters the detector to determine the quantitative content of the controlled substance.

The disadvantage of this device is the need for periodic calibration in a continuous mode of operation of the device, due to the fact that suspended particles, air bubbles and other foreign matter can settle on the membrane immersed in the test liquid.

The closest analogue adopted for the prototype of the invention is a flow-through ionometric cell [2, p. 245, Fig. 6.9] used in the Polymetron cyanide autoanalyzer. The device comprises a monolithic case with a measuring electrode and a reference electrode installed in it and with an internal flow channel having an extended section extending along the sensitive electrode surfaces of the measuring and reference electrodes and a short inclined segment (45 ° to the surface of the measuring electrode) connecting the input inlet tubes with the beginning of an extended section at the edge of the measuring surface of the measuring electrode. The end of the extended section of the internal flow channel is connected to the outlet of the outlet tube.

Due to the fact that the fluid flow is introduced at an angle to the surface of the membrane, it washes it well, preventing a decrease in sensitivity caused by “freezing” of air bubbles on the measuring surface of the electrode.

The disadvantage of the cell of the prototype is the significant distance between the electrodes (not less than the diameter of the electrode), located one after the other along the flow stream, which leads to the influence of the flow potential and distortion of the useful signal, which reduces the reliability of measurements.

The problem to be solved is to increase the reliability of measurement results.

Achieving the claimed technical result is achieved by minimizing the measuring volume of the cell and the distance between the electrodes in addition to eliminating the effect of “freezing” of air bubbles on the measuring surface of the electrodes.

The essence of the invention lies in the fact that in a flow-through ionometric cell containing a monolithic body with a measuring electrode and a reference electrode installed therein and with an internal flow channel having a first extended section and a first short inclined section connecting the inlet tube opening to the beginning of the first extended section, passing along the sensitive electrode surface of the measuring electrode, the housing is made in the form of a five-sided prism of polymer material, in a cylindrical recess which, made on the side of the corresponding faces of the prism, the measuring electrode, the reference electrode and the fittings of the tubes for supplying and discharging liquid are sealed, installed so that their axis of symmetry are located in the same plane with the axis of symmetry of the internal flow channel, which also has a second extended section extending along the sensitive electrode surface of the reference electrode, and a second short inclined segment connecting the end of the first extended section to the beginning of the second extended portion with an end connected to the opening of the tube for discharging the fluid, wherein the second short sloping segment directed in the opposite direction relative to the first angle segment and is perpendicular to the sensitive surface of the reference electrode electrode.

In addition, in the proposed flow measuring cell, the axis of symmetry of the pipe fittings for supplying and discharging liquid are parallel to each other at a distance equal to the diameter of the nozzle.

In addition, both short inclined segments are located at an angle of 45 ° ± 15 ° relative to the first extended section of the internal flow channel.

In addition, the measuring electrode and the reference electrode are fastened to the housing by means of threaded sleeves with gaskets, which makes it possible to quickly change the electrodes.

The invention is illustrated by the drawing of a flow-through ionometric cell.

The flow-through ionometric cell contains a monolithic body 1 in the form of a pentagonal prism, in which a measuring electrode 2, a reference electrode 3, and also a nozzle 4 of the tube for supplying liquid and a nozzle 5 of the tube for draining the liquid, the openings of which are connected through the internal flow channel of the cell, are mounted.

The housing prism has two parallel faces 6, 7 of different sizes, located at an angle of 45 ° to the horizontal, a face 8 perpendicular to it, a horizontal face 9 and a vertical face 10. In faces 6, 7 there are cylindrical recesses in which the fittings 4 and 5 are installed, the measuring electrode 2 is installed in a cylindrical recess of the vertical face 10, and the reference electrode is in the cylindrical recess of the face 8, while the axis of symmetry of the electrodes 2, 3 and nozzles 4, 5 are located in the same plane, and the symmetry axis of the nozzles 4, 5 are offset from each other at a distance ie, equal to the diameter of the nozzle.

The internal flow channel of the cell is located in the same plane with the axes of symmetry of the electrodes 2, 3 and fittings 3, 4 and has a curved shape, consisting of two extended sections 11, 12 and two short inclined segments 13.14, located with an inclination in opposite directions to each other from each other at an angle of 45 ° ± 15 ° relative to the first extended section 11. In this case, the input of the first extended section 11, passing along the sensitive electrode surface of the measuring electrode 2, is connected to the hole by means of the first inclined segment 13 Thieme tube nozzle 4 for supplying the liquid, and its second output via a second inclined segment 14 lying perpendicular to the electrode surface of the electrode sensitive comparisons 3 is connected to the input of the second elongated portion 12 of the inner flow channel. The output of the second extended section 12, passing along the sensitive electrode surface of the reference electrode 3, is connected to the hole of the nozzle 4 of the tube for draining the liquid.

To ensure the possibility of changing the electrodes, they are installed in threaded sleeves with gaskets that provide a tight seal in the housing. Fittings are also installed using gaskets.

The housing 1 is made of a transparent polymer material, inert to the reactions taking place in the cell, for example, polymethyl methacrylate (organic glass).

To use a flow-through ionometric cell, a pair of electrodes 2, 3 is selected, which provide selective detection of the content of ions of a controlled substance in a liquid.

The cell inlet tube is connected to a flow line supplying the test fluid under pressure using a peristaltic pump. The output tube is led to a container for collecting waste water. The terminals of the electrodes 2, 3 are connected to an ionometric detector, which can be used as a high-resistance voltmeter, calibrated in units of concentration of the analyte.

During the flow of the studied fluid in the internal channel of the cell due to metabolic processes occurring on the ion-selective membrane of the measuring electrode, an electrical potential arises at its output, the value of which depends on the activity of the ions of the substance being determined. The reference electrode, the potential of which does not change, serves to take a control signal.

High accuracy and stability of readings during measurements is ensured by the design features of the cell, as evidenced by tests of several designs of ionometric cells.

In the first embodiment, the electrodes were arranged sequentially along the flow of the studied fluid.

Tests of the cell showed that air bubbles often “hang” on the sensitive surfaces of the electrodes, which causes a decrease in their effective surface and, as a result, a sharp change in the measured potential. In addition, a significant distance between the electrodes (1-1.5 cm) leads to a noticeable influence of the flow potential and to significant short-term noises of unknown nature during the measurement process.

The second option was the design of the cell type "reflecting wall" according to the prototype of the proposed solution. In this design, the flow is supplied at an angle close to 45 ° to the surface of the measuring electrode, and then, as in the first embodiment, passes along the surface of a series-mounted reference electrode.

Compared with the first option in this design, the effect of "freezing" of air bubbles decreased by approximately 2-3 times. However, the influence of the flow potential and short-term noises of unknown nature remained.

In the third embodiment, we tested the design of the cell with an internal Z-type flow channel in which it was possible to minimize its working volume to 10–20 mm ³ and thereby reduce the noise level to 30% of the noise level in the cells of the first and second types.

However, the presence of acute-angled bends of the flow channel led to an increase in the effects associated with the “freezing” of air bubbles, the consequences of which are almost identical to their manifestation in the cell of the first type.

In the proposed design, it was possible to combine the advantages of the cells of the second and third type.

The introduction of a fluid flow at an obtuse angle to the surface of the measuring electrode 2 ensures its good flow wash. The increase in cell volume in the region of the reference electrode 3 due to the supply of the inclined section 16 does not affect the dynamic characteristics of the measurement process and at the same time provides easy removal of air bubbles in the liquid. The level of short-term noise of the proposed cell corresponds to the noise of the second type of cell (“reflecting wall”), and “freezing” of air bubbles was observed no more than once in 8 hours. The cell turned out to be practically insensitive to air bubbles specially introduced into the flow of the aqueous phase during the tests. In this case, the sensitive cell volume (the volume in the area of the indicator electrode), which is about 10 mm ³ , minimizes the response time of the detector to a change in the concentration of the component determined in the studied liquid.

Industrial applicability of the invention is determined by the fact that the proposed design can be made according to the description and drawing from known materials using known technology and used as a flow-through ionometric cell in continuous monitoring systems for the content of various substances in water in a wide range of their concentrations.

Bibliography

1. RF patent No. 2107286, IPC G01N 27/48, publication of March 20, 1998.

2. K. Kamman. Work with ion-selective electrodes. - M .: World. - 1980

3. RF patent No. 2125267 for invention, IPC G01N 35/08, publication January 20, 1999.

Claims (5)

1. Flow ionometer cell containing a monolithic housing with a measuring electrode and a reference electrode installed therein and with an internal flow channel having a first extended section and a first short inclined section connecting the inlet of the inlet tube to the beginning of the first extended section passing along the sensitive electrode surface of the measuring electrode, characterized in that the housing is made in the form of a five-sided prism of polymer material, in the cylindrical recesses of which, made from the side of the corresponding faces of the prism, the measuring electrode, the reference electrode and the fittings of the tubes for supplying and discharging liquid are sealed, installed so that their axis of symmetry are located in the same plane as the axis of symmetry of the internal flow channel, which also has a second extended section extending along sensitive electrode surface of the reference electrode, and a second short inclined section connecting the end of the first extended section with the beginning of the second extended section, the end of which connected to the hole of the tube for draining the liquid, and the second short inclined segment is directed in the opposite direction relative to the first inclined segment and is located perpendicular to the sensitive electrode surface of the reference electrode. 2. Flow-through ionometric cell according to claim 1, characterized in that the casing is made transparent. 3. The flow-through ionometric cell according to claim 1, characterized in that the short inclined sections of the internal flow channel are located at an angle of 45 ° ± 15 ° relative to the first extended section. 4. Flow-through ionometric cell according to claim 1, characterized in that the axis of symmetry of the nozzles of the tubes for supplying and discharging liquid are parallel to each other at a distance equal to the diameter of the nozzle. 5. Flow-through ionometric cell according to claim 1, characterized in that the measuring electrode and the reference electrode are fastened to the housing by means of threaded bushings with gaskets.