RU2105295C1 - Method determining concentration of electrolyte and gear for its implementation - Google Patents

Abstract

FIELD: analytical instrumentation. SUBSTANCE: method determining concentration of electrolyte poured into multilink cell connected to output of stabilized high-frequency generator includes irradiation of cell by electric signal, change of cell configuration thanks to series connection of pairs of electrodes of specified geometry in various combinations after equal time intervals, check of signal amplitude across output of cell and identification of sought-for concentration of electrolyte by configuration code when specified magnitude of amplitude is achieved. Gear for determination of concentration of electrolyte has multilink cell 2, stabilized high-frequency generator 1, multiplexer 3, microprocessor 5, comparator 4. Outputs of microprocessor 5 are connected to address inputs of multiplexer 3 which information inputs are connected to outputs of multilink cell 2. Input of cell is connected to output of stabilized high-frequency generator 1. EFFECT: increased authenticity of method and gear. 2 cl, 4 dwg

Description

 The proposed technical solution relates to physico-chemical research and can be used in chemical and other related industries.

 A known analog-frequency method for determining the concentration of electrolytes (Usikov S.V. Electrometry of liquids. L.: Chemistry, 1974, p.95-98.), Which consists in converting changes in the capacitance of the sensitive element with air and liquid in the corresponding change in the frequency and voltage of the generator and solving the obtained dependencies to determine the desired concentration of electrolyte.

 The disadvantage of this method is the low accuracy and efficiency associated with tuning the circuit in resonance, not a wide range of measurements.

 Known amplitude-frequency method for determining the concentration of electrolyte (Lopatin B. A. High-frequency titration with multi-link cells. M: Chemistry, 1980, S. 9-13.), Placed in a capacitive measuring cell with n links of the resonant frequency-defining circuit of the generator high frequency, and the selection of the resonant frequency according to the amplitude-frequency characteristic, including the measurement of frequency and voltage at regular intervals, the calculation of the electrolyte parameters from the measured frequency.

 The disadvantage of this method is the low accuracy and efficiency associated with the replacement of one cell with another, not a wide range of measurements, since each cell works only in its own range, a large methodological error due to the fact that the desired electrolyte characteristics, although found through the frequency, are by additional conversion through the amplitude-frequency characteristic.

 The closest is the frequency method for determining the concentration of electrolyte (see RF patent N2011983, G 01 N 27/02, 1994, bull. N 8), located in the capacitive measuring cell of the frequency-setting circuit of a high-frequency generator, including frequency measurement at regular intervals , changes in the geometry of the cell due to the sequential inclusion of electrodes in the variable frequency drive circuit in various combinations for which the ratio of the change in frequency to the current value of the frequency is determined, calculation of electrolyte parameters by frequency from the least th of them.

 The disadvantage of this method is the low efficiency associated with enumerating all combinations of a multi-link cell and the low reliability of measurements due to the use of only one model of the measuring cell and additional signal conversion.

 A device for determining the concentration of electrolyte (Usikov S. V. Electrometry of liquids. L.: Chemistry, 1974, p. 95-98.), Consisting of a high-frequency generator, in the resonant circuit of which is included a capacitive measuring cell, a recording device.

 The disadvantage of this device is the low accuracy and efficiency, which are associated with tuning the circuit to resonance, a wide range of measurements, limited by the resonant frequency of one cell.

 A device is known (Lopatin B. A. High-frequency titration with multi-link cells. M.: Chemistry, 1980, pp. 9-13.), Consisting of a high-frequency generator, the circuit of which includes a multi-link capacitive measuring cell.

 The disadvantage of this device is the low accuracy, limited measurement range, since each cell operates only in its own range, a sufficiently long time for one experiment, associated with the introduction of jumpers for sequential switching over time of the electrodes of the multilink cell.

 The device (RF Patent N 2011983, G 01 N 27/02, 1994, bull. N 8), consisting of a high-frequency generator, in the frequency-setting circuit of which, with the help of a bidirectional multiplexer, includes a multi-link capacitive cell, and microprocessor, the input of which is connected to the generator, and the output to the multiplexer.

 The disadvantage of this device is the large time of the experiment due to the measurement of the signal frequency for all possible combinations of electrodes of the multi-link cell and the limited measurement range associated with the use of an electrolytic cell of the same type.

 The aim of the proposed technical solution is to increase the efficiency of determining the characteristics of electrolytes and the reliability of measurements.

The goal is achieved by:
1. In the method for determining the concentration of electrolyte placed in a multi-unit cell, including irradiating the cell with an electric signal, changing the configuration of the cell due to the sequential inclusion of pairs of electrodes of a given geometry in various combinations at regular intervals, in contrast to the prototype, the cell is connected to the output of a stabilized generator of high frequency, control the amplitude of the signal at the output of the cell, when the specified amplitude value is reached, the desired end is identified by the configuration code ntration of electrolyte.

 2. In the device for determining the electrolyte concentration, containing a multi-link cell, a stabilized high-frequency generator, a multiplexer, a microprocessor, the output of which is connected to the address inputs of the multiplexer, the information inputs of the latter are connected to the outputs of the multi-link cell, an additional comparator is introduced, the input of which is connected to the output of the multiplexer, the output is connected to the microprocessor, and the multi-link cell is connected to the output of the high-frequency generator.

 When analyzing well-known technical solutions, no solutions were found having features similar to the distinguishing features of the claimed solutions. The presence of a set of essential features will provide increased efficiency in determining the characteristics of electrolytes and the reliability of measurements.

 In FIG. 1 and 2 as an example, a physical model of a multi-link capacitive cell and its equivalent equivalent circuit explaining the essence of the method.

 The essence of the proposed method is as follows.

, помещают во внутреннюю полость B многозвенной ячейки (фиг. 1). Последовательно включают ее пары электродов в различных сочетаниях p=ij (где i=j;

) на выходе генератора высокой частоты. Например: 1-2; 1-3; 1-4; 1,2-3,4; 1,2-4,5; 1,2-5,6 и так далее. Общее число всех возможных сочетаний

,
где m=2.The studied electrolyte solution with specific electrical conductivity κ _ij functionally associated with concentrations

, placed in the internal cavity B of the multi-unit cell (Fig. 1). Consistently include its pairs of electrodes in various combinations p = ij (where i = j;

) at the output of the high-frequency generator. For example: 1-2; 1-3; 1-4; 1.2-3.4; 1.2-4.5; 1.2-5.6 and so on. The total number of all possible combinations

,
where m = 2.

 Carrying out the above sequence of actions, thereby changing the geometric parameters of the cell, that is, enhance or exclude the action of individual elements of the equivalent circuit equivalent cells (Fig. 2).

Consider the equivalent circuit equivalent circuit ij of the cell, consisting of the active resistance of the solution R _{ij of the} capacitance determined by the dielectric constant of the solution C2 _ij , the vessel wall capacitance C1 _ij , the cell constant K _ij , the cell wall thickness d, the distance between the electrodes lcp _ij , and the absolute dielectric constant E ₀ , the dielectric constant of the cell wall material E ₁ , the effective area of the inner plates S1 _ij , the effective area of the external electrodes S2 _ij .

.The parameters of the circuit are determined by the following expressions

.

,
где i - мнимая единица;

.The complex resistance of the equivalent equivalent circuit (Fig. 2) is equal to

,
where i is the imaginary unit;

.

.The total impedance of the cell Z, which determines the amplitude of the output signal, is equal to:

.

It follows from formula (6) that the impedance Z depends on the quantities R, ω, C1 _ij , C2 _ij . In the proposed method, ω = const, R is determined by the conductivity of the solution, and C1 _ij and C2 _ij are determined by the method of switching on the electrodes of the multi-unit cell, that is, the code N _{ij of the} switch. In this way
Z = φ (κ, N _ij ) (7).

And the conductivity and concentration of the electrolyte solution can be determined by the impedance values Z and the switch code N _ij . In the proposed method, the Z values are not measured, but the signal amplitude is checked with the selected threshold value. Therefore, Z = const.

.Hence

.

 The complexity of dependencies (5) and (6) does not allow us to obtain the conductivity value (8) in an explicit form; therefore, it is proposed to use the approximation of the graded characteristic as dependence (8).

 In FIG. 3 shows a structural diagram of a device that implements the proposed method.

 The device consists of a stabilized high-frequency generator 1, multi-unit cell 2, multiplexer 3, comparator 4, microprocessor 5.

 Generator 1 is designed to irradiate cell 2 with high frequency currents.

 Multiplexer 3 is necessary for switching in various combinations of electrodes of multi-unit cell 2.

 Comparator 4 is designed to control the amplitude of the signal at the output of cell 2.

 The microprocessor 5 is necessary for controlling the multiplexer 3, as well as calibration, normalization and calculation of the characteristics of the electrolyte.

соответствует свой импеданс Z_ij, а значит и амплитуда A_ij. Микропроцессор 5, коммутируя электроды ячейки 2, подбирает конфигурацию ячейки 2, добиваясь получения заданного значения импеданса Z_зад., что контролируется с помощью компаратора 4. По коду конфигурации N_ij рассчитывается искомая концентрация электролита.The device operates as follows. Cell 2 is irradiated with a signal generated by the generator 1, with a fixed frequency f _reg. and amplitude A ₀ . When the signal passes through cell 2, the amplitude drops to the value of A _x , since each concentration value

corresponds to its impedance Z _ij , and hence the amplitude A _ij . The microprocessor 5, switching the electrodes of the cell 2, selects the configuration of the cell 2, achieving a given value of the impedance Z _ass. , which is controlled using the comparator 4. According to the configuration code N _{ij, the} desired electrolyte concentration is calculated.

 Let us prove the effectiveness of the proposed solution in relation to the prototype.

By efficiency:
The number of measurements during the experiment for the prototype is equal to the number of combinations n of the multi-link cell. With this method, for an experiment it is enough to make from 1 to n measurements, depending on the electrical conductivity of the electrolyte. If the distribution density of the conductivity is uniform, then the experiment time is halved.

.In connection with the replacement of the frequency measurement by the amplitude control, the time of one measurement is reduced. The average response time of the comparator is t ₁ = 150 ns with an error δ of less than 0.1%. To achieve such accuracy of frequency measurements, m binary digits are required:

.

When the signal frequency f = 1 MHz, the measurement time will be t ₁ for the proposed solution and t ₂ for the prototype.

.

.

 Thus, the time of one measurement is reduced by at least 6 thousand times, and the experiment time is not less than 13 thousand times.

,
где Q₁ - достоверность измерений предлагаемого решения; Q₂ - достоверность измерений прототипа.By reliability:
The effectiveness of the proposed solution

,
where Q ₁ - the reliability of the measurements of the proposed solution; Q ₂ - the reliability of the measurements of the prototype.

Reliability is determined by the number of models reflecting the experiment. For the prototype, there is only one model - a capacitive type cell. Therefore, Q ₂ = 1.

For the proposed solution, due to the inclusion of a cell at the output of the generator, it is possible to use inductive and capacitive cells of parallel and serial type, therefore Q ₁ = 4.

.

.

 Thus, the reliability of measurements of the proposed solution is increased by 4 times. Which, in the end, increases the same amount of flexibility. The range of applied solutions and the range of measurements are expanding due to the use of cells of various types.

The implementation of the method is carried out in a conductivity meter "TEMP-078" based on a personal computer "Sirius" with a three-bus architecture and microprocessor Z-80. The generator and comparator are made on the basis of the IC 564 series. A multi-unit capacitive cell with 5 ring electrodes made of copper foil:
The diameter of the cell D, mm - 24
The thickness of the cell walls d, mm - 2
The height of the electrodes h, mm - 20
The distance between the electrodes lcp _ij , mm - 7
The results of experiments conducted on model NaCl solutions with a contactless conductometric cell are presented in FIG. 4.

 Thus, the concentration control by code using the proposed conductivity meter with a switch and corresponding converters, in contrast to the known solutions, increases the reliability of measurements by 4 times and reduces the measurement time by at least 13 thousand times.

Claims (2)

 1. The method of determining the concentration of electrolyte placed in a multi-unit cell, including irradiating the cell with an electric signal, changing the configuration of the cell by sequentially connecting pairs of electrodes of a given geometry in various combinations at regular intervals, characterized in that the cell is connected to the output of a stabilized high-frequency generator, the amplitude of the signal is monitored at the output of the cell; upon reaching the specified amplitude value, the desired concentration is identified by the configuration code ju electrolyte.  2. A device for determining the electrolyte concentration, containing a multi-link cell, a stabilized high-frequency generator, a multiplexer, a microprocessor, the output of which is connected to the address inputs of the multiplexer, the information inputs of the latter are connected to the terminals of the multi-link cell, characterized in that a comparator is introduced, the input of which is connected to the output multiplexer, the output is connected to the microprocessor, and the multi-link cell is connected to the output of the high-frequency generator.

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