SU1023234A1 - Meter of impurity concentration in liquid or gaseous media - Google Patents

Abstract

METER impurity concentration in the liquid or gaseous SREDAH.soderzhaschy EMF recorder connected to the sensor, designed as a firmly 9lektrolitnoy galvanic cells, equipped with a fixed potential terminal, and a metal case which simultaneously serves as a cold end, the potential K1VOD cell body mounted axially and separated from it is insulated, and it is so that, in order to reduce leakage currents through the insulation and increase the accuracy of measurements, the distance between the housing and the potential th guard electrode terminal installed in a hollow body closed section and recorder provided with a device for supplying a protection electrode potential, equal to the measured emf. The invention relates to the technique of controlling impurities in a harsh or gaseous environment and can be widely used in the national economy, in particular in the metal industry, for example, to control the process of refining non-ferrous metals, (for example) to control the content of .. oxygen impurity. in the melt of evin-tsa, used as a wire cable.

Description

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W 4 A meter is known that contains a galvanic cell and secondary recording devices 1. The disadvantage of this meter. This is because during the operation a decrease in the electrical resistance of the insulation is induced, which leads to an increase in leakage currents and a decrease in the accuracy of the EMF measurement. The closest technical solution to the invention is an impurity concentration meter in liquid or gaseous media-x, containing an EMF recorder connected to a Sensor made in the form of a solid electrolyte galvanic cell, equipped with a potential output and installed in a single metal case, which simultaneously serves as a terminal moreover, the potential output of the cell is installed axially to the casing and is separated from it by an insulation {2J. The purpose of the invention is to reduce leakage current through insulation and to improve measurement accuracy. The goal is achieved by the fact that in a concentration meter in liquid or gaseous media, with a holding EMF recorder, are connected to a sensor made in the form of a solid electrolyte galvanic cell fitted with a potential output and installed in a metal case that simultaneously serves as a discharge, and the potential is 2 times. conclusion . whose ki is installed axially and separated from it by insulation, in which a guard electrode in the form of a hollow body of a closed section is installed between the case and the potential output, and the recorder is equipped with a device for applying a potential equal to the measured electromotive force to the guard electrode. The scheme of the proposed impurity concentration meter in liquid and gaseous media. The meter contains a sensor in the form of a solid electrolyte galvanic cell 1, which is installed in a metal case 2, simultaneously serving as a terminal and connected to an external electrode, which serves as the analyzed medium. Electrode 3 is located between the metal case 2 and the solid electrolyte galvanic cell 1. The solid electrolyte galvanic cell 1 contains the reference electrode 4, which is connected by a potential output 5 with a device 6 for applying a potential equal to an electromotive force in the form of a hollow body. a cross section installed in isolation 3. A sensor in the form of a solid electrolyte cell 1 is connected to the EMF recorder 8 .. The meter works in one of the following ways. The solid electrolyte cell 1 converts the difference in the concentrations of the contact impurity in the analyzed medium and the reference electrode 4 into the EMF, which is fed to the input of the device 6 for potential supply; equal) to the emf on the guard electrode 7 and measured by the recorder 8. A potential equal to the measured emf is applied from the output of device b, with the transmission coefficient of device 6 equal to one, i.e. where K is the transmission coefficient of the repeater; EC is the measured EMF; potential at the guard electrode 7. The voltage of the electrolysis of 3 between the potentized output 5 and the OHMI electrode 7 is determined by the difference. (2) where uE is the voltage at the electrical insulation. After the substitution () (2) we get that). (3) Let us express the electrical resistance of the insulation 3 through the leakage current and the voltage across it EsH-xl U Similarly to a meter without an ohlad electrode, we can write here R and 1e are the electroresistance; isolation of the insulation 3 between the potential terminal 5 and the guard electrode 7 and leakage through it; R and I - electro. the resistance of the interelectrode isolation of the leakage current through it; the solid state electrolyte galvanic cell without a guard electrode. Taking into account that the materials used by electrically insulating materials are the same, we can consider their electrical resistance equal. From this, we obtain l.lU-K), 16). E. Leakage current across the insulator 3 between the otypical terminal 5 and the guard electrode 7 in the limit tends to the bee when approaching the unit coefficient

Claims (1)

(54) The unit is mounted axially to the case and is isolated from it by isolation, so that, in order to reduce leakage currents through the insulation and improve measurement accuracy, the isolation between the case and the potential The protective electrode in the form of a hollow body of a closed cross section is installed with the final output, and the recorder is equipped with a device for supplying to the security electrode a potential equal to the measured EMF. The invention relates to techniques for controlling impurities in liquid or gaseous media and can be widely used in the national economy, in particular in the metallurgical industry, for example, to control the process of refining non-ferrous metals? ”. Tall, in 1 for example, to control the content., j. impurities of oxygen in the melt, used as a cable cable. . cable industry, f /% for content control. · "* · _H svin- obolrch ·