RU2046361C1 - Device for measuring specific electric conduction of liquids - Google Patents

Abstract

FIELD: measuring devices. SUBSTANCE: device has sensor, which is designed as cylinder which is made from solid dielectric material. In its housing disk and ring electrodes are mounted. Electrodes are connected to voltage recorder. Disk electrode is connected through serial circuit of current recorder and variable resistor to power supply. Technological process power supply is used as power supply for device. EFFECT: increased functional capabilities. 1 dwg, 1 tbl

Description

 The invention relates to measuring equipment, in particular to devices for measuring the electrical conductivity of liquid media under the action of external current sources, including local volumes with low current density.

A known sensor containing a ceramic body with a channel for the conclusions and the measuring cavity, two current electrodes, three potential probes connected to the measuring cavity. The ceramic case is open bottom. Between the upper end and the measuring cavity of the ceramic body there is a channel for blowing the cavity with an inert gas [1]
The disadvantage of this device is the impossibility of measuring the electrical conductivities of liquid media under conditions of simultaneous flow of current from an external source through it. This is due to the fact that the measurement is carried out from an internal current source. If there is an external source of current in the measuring cavity, it will be equal to the sum of two currents: internal and external, which introduces large errors and invalidates the measurement results. This excludes the possibility of measuring the electrical conductivity in the unit with a continuous flow of a working current through a liquid medium, for example, a charge melt in an aluminum electrolysis cell. In the latter, in the operating mode, the possibility of even a short-term shutdown of the operating current is excluded. In addition, the sensor is complex in design.

A known contact sensor containing a dielectric tube with three ring electrodes, one of which is located outside, and two inside flush with the surface of the tube wall, a voltage recorder, ammeter, variable resistor, contains an internal current source and a switch, while the external electrode and one of the internal the electrodes are located in the middle of the tube, the internal electrodes are connected through a voltage recorder located in the middle of the tube, the outer and inner electrodes are connected in series o On-off switch, ammeter, current source and variable resistor [2]
The disadvantage of this device is the close dependence of the magnitude of the current flowing along the measured portion of the medium under investigation inside the sensor, on its spatial orientation relative to the equilibrium current lines. Since a power current flows through one of the narrow ring electrodes included in the measuring circuit of the voltage recorder, polarization processes are actively taking place on it. As a result of this, the accuracy of measuring the electrical conductivity of the test medium decreases.

The closest in technical essence to the proposed is a device for measuring electrical conductivity, which is made in the form of a dielectric tube with current and ring measuring electrodes, of which the current and one of the measuring electrodes are located inside the tube, contains an ammeter, recorders, additionally contains a variable resistor connected through an ammeter to ungrounded current electrodes made in the form of disks separated from each other by an insulating gasket, while nye electrodes connected to the first DVR, placed respectively over the inner measuring electrode and the nearest current electrode that are connected to a second registrar [3]
The device is specialized, and when measuring the electrical conductivity of liquid media at low currents, its accuracy decreases, since the measured current becomes comparable with the error of the ammeter. With a decrease in the resistance value of a variable resistor, the current passing through a portion of the medium under study located inside the sensor tube increases. This increase is possible to the limit limited by the total electrical resistance of the lead wires and ammeter. If the electric field strength in this section of the medium under study is small, then the magnitude of the current strength from external current sources turns out to be small. At very low electric field strength and current density from external current sources, it turns out to be close to the error in measuring the current strength with an ammeter. The device does not significantly affect the measurement accuracy by actively interfering with the measurement process. So, for small values of the electric field strength and current density from external sources, an increase in the current strength in the studied section of the electric circuit inside the sensor tube is possible only by reducing the resistance value of the variable resistor to zero. A further increase in the current strength to increase the accuracy of measuring the electrical conductivity of the medium is impossible. A significant drawback of this device is the obligatory orientation of the sensor along the current lines. This requires special devices for orienting the sensor, which leads to an increase in the cost of this device.

 The purpose of the invention is the creation of a device for measuring electrical conductivity, the design of which would provide an increase in the accuracy of measuring the electrical conductivity of the studied media in volumes with minimum current densities from external sources.

 The essence of the invention lies in the fact that the device for measuring electrical conductivity, comprising a sensor with a disk and ring electrodes located therein, a current recorder and a voltage recorder connected between the disk and ring electrodes, a variable resistor, a device for installing the sensor in the studied local volume, it additionally contains a glass made of dielectric material, and the disk electrode through a current recorder and a variable resistor is connected to a third-party power source Niya.

 The device allows not only to measure in a liquid medium under the influence of external sources of current, but also to use these sources in the measurement process. By changing the resistance value of the variable resistor, you can affect the accuracy of the measurement and get good results even with small process currents from third-party sources, i.e. those currents that flow through the liquid medium in the unit. This is possible due to the fact that when connecting the current disk electrode to one of the terminals of the power source from the electric circuit, a section with a much greater resistance than the resistance of the insulating strip in a known device is excluded. In the proposed device, the cross section of the excluded section of the electric circuit corresponds to the effective cross section of the bathtub of the unit, to which current flows in the volume of the unit, and the length is the distance from the sensor’s disk electrode to the unit’s electrode, which is connected to one of the terminals of the power source. This distance can also be many times the length of the prototype insulation strip. With decreasing resistance of a variable resistor, the intensity and current density in the measured area of the medium under study increase. Thus, the current strength can be increased so much that the measurement error of the current recorder has a negligible effect on the measurement result. The voltage drop between the electrodes will be proportional to the electrical conductivity of the medium.

 When immersed in the test medium, the sensor is filled with liquid. The volume of liquid is strictly fixed and depends on the geometric dimensions of the sensor. When current flows from an external source on the electrodes, a potential difference arises, which depends on the electrical conductivity q of the medium under study and the geometry of the liquid volume inside the sensor. To reduce the polarization phenomenon, the current electrode is made in the form of a solid disk. To interrupt the parallel circuit, which could close the disk and ring electrodes in the test medium from the outside of the sensor, the base of the glass is made of dielectric material.

 To increase the accuracy of measuring q by the device, it is necessary that the equi-current lines are parallel when approaching the ring electrode. For this, the electrode is located in the middle of the glass. Due to this, a section with an inhomogeneous electric field is excluded from the measuring circuit. The measurement accuracy q is not determined by the location of the sensor relative to the equilibrium current lines. For any arrangement of the device in the space under study, the current strength in the measuring circuit will remain quite high for small values of the quenching resistance R.

 Thus, a comparison of the claimed solution with other technical solutions shows that the introduced element is widely known, its introduction in this connection with other elements of the device, technological unit and a third-party power source, their relative position lead to the appearance of the new above properties, which allow to increase the measurement accuracy of specific electrical conductivity of liquid media at low process currents from an external source.

 This makes it possible to conclude that the proposed technical solution meets the inventive step.

 The drawing shows a functional diagram of a device for measuring electrical conductivity.

 The device comprises a conductivity sensor consisting of a cup 1 made of dielectric material, a disk 2 and a ring 3 electrodes, as well as a voltage recorder 4, a current recorder 5, and a variable resistor 6.

 The electrodes 2 and 3 are interconnected via a voltage recorder 4. The disk electrode 2 through the current recorder 5 and a variable resistor 6 is connected to one of the terminals of the power supply 7.

 A glass made of a dielectric material serves to isolate a local space with a limited and precisely known volume from the investigated medium. At high operating temperatures and in an aggressive environment, the glass can be made of polyvinyl chloride, textolite, and fluoroplastic. At higher temperatures from materials with a higher melting point, such as alunda.

 The bottom of the glass is made of the same solid material as the walls of the glass. In contrast to the proposed device in the prototype device, the insulating gasket is made of a dielectric in one of the state of aggregation: solid, liquid, gaseous. In particular, the gasket may be made of air having a sufficiently high dielectric constant. In the proposed device, the bottom of the glass cannot be liquid or gaseous, since in this case the disk electrode will come into contact with the test medium on the other side of the glass. In this case, an additional current will flow through the current recorder, which will introduce significant errors into the measurement process.

 The disk electrode senses all the working current flowing through the sensor, therefore, has a larger area. The polarization is reduced, as the current density decreases with increasing area. Small currents flow through the measuring electrode compared to the current electrode. The effect of polarization is minimal. The electrodes are made of a material with high electrical conductivity and a low tendency to surface polarization. At a significant temperature of the studied liquid medium, the electrode material should have high heat resistance, and with increased aggressiveness of the medium, good corrosion resistance or heat resistance. Both electrodes can be made of platinum, stainless steel, and at high temperatures of zirconium diboride, silicon carbide.

(10-20) U_xx (1) где U_xx напряжение холостого хода стороннего источника питания технологического агрегата, в котором производится измерение, В.The variable resistor 6 performs the function of a quenching resistance and limits the maximum permissible current I _gmax flowing through the sensor’s disk electrode within 0.05-0.1 A. Its nominal value R is calculated by the formula R

(10-20) U _xx (1) where U _xx is the open circuit voltage of the external power supply of the technological unit in which the measurement is carried out, V.

An increase in the current strength above I _gmax leads to a significant activation of polarization processes on the electrodes and a decrease in the measurement accuracy (see Yossel, Yu.Ya. Electric fields of constant currents. L. Energoatomizdat, 1986, p. 59, 81).

 To place the sensor in the test medium, the device is equipped with a rod, for example, in the form of a hollow rod (not shown in the drawing), fixed to the middle of the sensor glass. If necessary, the rod is made of heat-resistant and heat-resistant materials, connecting wires are laid inside it.

 The device operates as follows.

 The sensor is immersed in the test fluid through which electric current flows, for example, in a slag bath during electroslag remelting, during electroslag surfacing, welding, etc. A variable resistor sets the current in the measuring circuit, not exceeding 0.05-0.1 A (with a further increase in current strength, the polarization of the disk electrode increases, interference in the process increases, sensors of large sizes and a larger diameter of the lead wires are required). Then, the readings of the current and voltage recorders are recorded.

·

сим·м^-1 (2) где I сила тока по показанию регистратора тока, А;
U напряжение по показанию регистратора напряжения, В;
l расстояние между электродами, м;
S площадь поперечного сечения дискового электрода, м².The conductivity of the medium under study is found by the formula q

·

sim · m ^-1 (2) where I is the current strength as indicated by the current recorder, A;
U voltage according to the voltage recorder, V;
l distance between electrodes, m;
S cross-sectional area of the disk electrode, m ² .

сим·м^-1 (3)
Ввиду малых токов, идущих через регистратор напряжения, измерительный электрод практически не подвергается поляризационным процессам. В целом точностные характеристики устройства при I ≅0,05-0,1 А практически не зависят от поляризационных процессов.K l / S is a constant value and depends on the geometric dimensions of the sensor. Finally q K

sim m ^-1 (3)
Due to the low currents flowing through the voltage recorder, the measuring electrode is practically not subjected to polarization processes. In general, the accuracy characteristics of the device at I ≅ 0.05-0.1 A are practically independent of polarization processes.

Metrological device characteristics obtained in the comparative measurement of KCl solution at 20 ^{° C} normal concentration of 0.1 N. The results are shown in the table.

 The proposed device in comparison with the prototype allows with greater accuracy to measure the electrical conductivity of liquid media at low current densities from an external current source. The device is simple in design. The measurement process is simpler than using a prototype device.

Claims (1)

 DEVICE FOR MEASURING ELECTRIC CONDUCTIVITY OF LIQUID MEDIA, comprising a dielectric tube with disk and ring electrodes located therein, a dielectric spacer located close to the disk electrode and forming a glass together with the dielectric tube, a voltage recorder connected between the disk and ring electrodes connected to the disk electrodes and series-connected current recorder and a variable resistor, characterized in that the bottom of the glass, which is a dielectric rokladku, and the solid formed from the same dielectric material and the same thickness as the tube, and as a power source used for the measurement of the power supply process to the output of which is connected the second terminal of the variable resistor.

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