SU697903A1 - Device for testing polarographic instruments - Google Patents

Description

(54) DEVICE FOR CONTROL OF POLAROGRAPHIC DEVICES

Claims (1)

The invention relates to electrochemical instrumentation and is intended to monitor the operability and determine the basic metrological characteristics of polarographic equipment in the process of its creation and operation. A device for controlling polarographic devices is known in the main auth. No. 577448, which reproduces the basic electrically (nonlinear and frequency) properties of the polarographic, cells with a stationary working electrode and, when connected to polarograms, of different types or other volt-amp equipment allows to obtain real polarization-like curves. The device consists of a fractionally differentiating amplifier and semiconductor diodes, while in the feedback circuit the anti-parallel connected circuits are included: the first consisting of a series-connected EMF source and a diode, and the second of two counter-coupled diodes and an EMF source, and the input terminals are connected through the skin; Ezistory with output, amplifier, eauntirovanny capacitor. However, since currents flow through the device, the magnitude of which corresponds to the real cell currents, and the latter are very small at ordinary polarographic concentrations, it is difficult to perform the necessary signal transformations inside the device with the required accuracy. The device reproduces only one-electron electrochemical reactions. In addition, a change in the concentration depolarizer can be reproduced in the device. Only by replacing all three identical diodes with their selection for the corresponding reverse current. At low concentrations of the depolarizer, the required reverse currents of the diodes are significantly less than those of actually existing diodes and, therefore, for such conditions the device is unrealizable. The aim of the invention is to improve the accuracy of the operation of the device and to expand the possibilities of control of polarographic equipment. The goal is achieved by introducing two adjustable scale amplifiers and a voltage to current converter into the proposed device for controlling polarographic devices, with the input of the first scale amplifier connected to resistors (to the point where the resistors connect to the capacitor) and output to the non-linear two-pole input which are counter-parallel connected circuits: the first consisting of a series-connected EMF source and a diode, and the second one of two counter-coupled diodes and an EMF source od which conn chen to the input of the second scaling amplifier output connected to the input of the last parallel interconnected fractional differentsiruyuscheg amplifier current and voltage in the transducer current The drawing shows a diagram of Proposition Guy device. The device contains terminals 1, 2 and 3, which are, respectively, indicator, auxiliary and comparing electrodes of a three-electrode cell; resistors 4 and 5 correspond to the volume resistance of the solution; capacitor b displays the capacitance of the two electric layer at the boundary of the indicator electrode with the solution in which and is the voltage corresponding to the polarizing potential at this boundary; nonlinear two-terminal formed by diodes 7, 8 and and sources EMF 10, 11; fractionally differentiating current amplifier 12; large-scale amplifiers 13, 14; a voltage to current converter 15. A polarizing potential U is applied to the input of the first large-scale amplifier 13, which must have a high input resistance so that its input current can be neglected. The nonlinear two-port device is connected to the output of the large-scale amplifier 13, due to which it is cut off from the external circuits of the device and does not directly affect the diffusion current Od. The output current of the nonlinear two-pole is fed to the input of the second large-scale amplifier 14, at the output of which a voltage proportional to the stationary component 3gj of the diffusion current is formed. The voltage converter to the current 15 supplies the output stationary current J to a real scale and provides output resistance. A fractional differential amplifier 12 serves to formulate a transient 3-co-current diffusion current. The first mastamp amplifier 13 allows for discrete scaling of the signal with a x abscissa, which is equivalent to a change in the number of reacting electrons. The second scale amplifier 14 changes the scale of the signal along the ordi- nate axis (current scale), which allows the signal to be converted at sufficiently high levels and reproduce the measurement of the depolator concentration without changing diodes 7, 8 and 9. Using scale amplifiers 13 and 14 and a converter the voltage to the current 15 allows: first, to separate the nonlinear two-terminal circuit consisting of diodes 7, 8 and 9 and sources of emf 10, 11 from the input circuits and thereby to process the signal at sufficiently high levels, which improves the accuracy of operation at troystva. Secondly, by changing the scale of the signal on the abscissa axis, the number of reacting electrons can be changed. Third, changing the scale of the signal along the ordinate axis allows changing the concentrations of the depolarizer, so that you can get by with one device instead of a whole series of devices designed for fixed concentrations of the depolarizer. Claims of the Invention A device for monitoring polarographic devices according to the author. No. 577448, characterized in that, in order to increase the accuracy and enhance the control capability of polarographic devices, two adjustable scale amplifiers and a voltage-current converter are introduced in it, the input of the first scale amplifier being connected to the resistors. to the input of a non-linear two-pole device whose output is connected to the input of the second large-scale amplifier, the output of the latter is connected to the inputs of a fractional-differentiating current amplifier and voltage-current converter connected in parallel.