SU1148002A1 - Device for measuring resistance of electrochemical resistors - Google Patents

Abstract

1. A DEVICE FOR MEASURING THE RESISTANCE OF ELECTROCHEMICAL RESISTORS, containing a three-electrode electrochemical cell, one of the electrodes of which is an electrochemical resistor, an adjustable polarization voltage source, the first indicator, characterized in that, in order to improve the measurement accuracy, two controls are introduced into it a switch, an operational amplifier, a resistor, a controlled source of measuring current, the first sampling and storage unit, a synchronizer, and the output of the controlled source of voltages The polarization is connected to the first information input of the first switch. the output of which is connected to the non-inverting input of the operational amplifier, the output of which is connected through a resistor to the auxiliary electrode of the electrochemical cell and to the second information input of the first switch, and also directly to the first information input of the second switch, in which the second information input is connected to the reference electrode of the electrochemical cell, output - with an inverting input of an operational amplifier; an electrochemical resistor is connected to a source controlled meter current and with the first block 3 of sampling and storage, and the control (the power inputs of both switches, the source of measuring current and the first block of sampling and storage are connected to the outputs of the synchronizer, and the first indicator is connected to the output of the first sampling and storage unit. 2. The device according to claim 1, wherein the operation is carried out in order to expand the functional capabilities, i.e., measure the polarization current 00 and form a constant voltage proportional to this current, the second unit you entered (storage and storage, connected line: tionary to the terminals of the resistor, the control input of the second kschy sample and hold unit connected to one of the synchronizer outputs, and connected to its output vtoryy indicator.

Description

f1 The invention relates to the field of chemotronics and electrochemistry and can be used in the measurement of characteristics, thin-film electrically chemical resistors, adjustable resistors and chemotrun devices. A device for measuring the resistance of an electrochemical resistor placed in a three-electrode electrochemical cell is known. Electrodes of an electrochemical cell are an auxiliary electrode, to which a polarization voltage is applied, a comparison electrode, the output voltage of which serves as a parameter in measuring the resistance, and this voltage is changed by applying a polarization voltage, i.e. by changing the polarization current through the cell, the working electrode, relative to which the output voltage of the reference electrode is measured. As a working electrode, the electrochemically studied PZ resistor is used. To measure the resistance of the electrochemical resistor, an alternating measuring current is passed through it and the voltage drop is measured at different values of the voltage on the reference electrode or the polarization current flowing through the electrochemical cell. The drawback of the device is the error in measuring the resistance due to the parasitic component of the alternating measuring current flowing through the solution in parallel to the electrochemical resistor under study. The closest to the proposed technical entity is a device for measuring an electrochemical resistor that contains a three-electrode cell, one of the electrodes of which is the electrochemical resistor under study, an adjustable polarization voltage source, a source of direct measuring current, indicator 2, for measuring resistance through an electrochemical resistor a constant measuring current is passed and a voltage drop across it is measured at different voltages on either the reference electrode or polarization. 2 A disadvantage of the device is the measurement error of the resistance due to the influence of the polarization current on the measurement result, since the polarization current flows through the electrochemical resistor simultaneously with the measuring current and creates together with the last the measured voltage drop. Due to imparting a complex symmetric shape to an electrochemical resistor relative to its grounded (common) point, the influence of the polarization current on the measurement result cannot be completely eliminated, since both symmetric parts of the resistor will always have a variation in resistance due to the finite accuracy of their production. . In addition, the potential difference arising at the ends of the electrochemical resistor under the action of the measuring current leads to an additional redistribution of the polarization current between both parts of the electrochemical resistor and, consequently, to additional distortions of the measurement result. The purpose of the invention is to improve the measurement accuracy of the resistance of the electrochemical resistor and enhance the functionality. The goal is achieved by the fact that a device for measuring the resistance of electrochemical resistors, containing a three-electrode electrochemical cell, one of the electrodes of which is an electrochemical resistor, an adjustable polarization voltage source, the first indicator, two controlled switches, an operational amplifier, a resistor, control measuring current source, the first sampling and storage unit, a synchronizer, the output of the adjustable polarization voltage source being connected to the first the first information input of the first switch, the output of which is connected to the non-inverting input of the operational amplifier, the output of which is connected through a resistor to the auxiliary electrode of the electrochemical cell and to the second information input of the first switch, and also directly to the first information input of the second, switch that has the second information input connected with an electrode for comparison of the electrochemical cell, and you are bsod –Ch with an inverting input of the operational amplifier, electrochemical cutting Torr connected to controllable source of measuring current and to a first sample and hold unit with the control inputs of the two switches, the measurement current source and the first sampling and storing unit connected to the outputs of the synchronizer and to the output of the first sample and hold unit connected to the first indicator. In addition, in order to expand the functionality, namely, the measurement of the polarization current and the formation of a constant voltage proportional to this current, a second sampling and storage unit is introduced connected in parallel to the outputs of the resistor, and the control input of the second sampling and wound unit is connected. with one of the synchronizer outputs, and a second indicator is connected to its output. FIG. 1 shows a functional diagram of the proposed device; in fig. 2 - time diagrams of his work. The device contains an adjustable source of polarization voltage 1 (e.g., linearly varying), first 2 and second 3 switches, operational amplifier 4, resistor 5 (Cc), three-electrode cell 6, the working electrode of which is an electrochemical resistor 7 ( R |), controlled source of measuring current 8, synopropatopop 9, first, block 10 of sampling and storage, first indicator 11, second block 12 of sampling and storage and second indicator 13. The output of source 1 is connected to the first information input of the first switch 2, output which It is connected to a non-inverting input of amplifiers 4. The output of amplifiers 4 is connected through a resistor 5 to the auxiliary electrode of the electrochemical cell 6 and to the second information input of the first switch 2, as well as directly to the first information input of the second switch 3, in which the second information input is connected to the electrode comparison of the electrochemical cell 6, and the output is connected to the inverting input of the operational amplifier 4. The electrochemical resistor 7 is connected to a controllable source 8 of measuring current the first block 10 of sampling and storage, the output of which is connected nepBbrii indicator 11. The control inputs of both switches 2 and 3, the measuring source 8, the current and the first block 10 are connected to the corresponding outputs of the synchronizer 9. The second block 12 of the sample and storage is connected in parallel with the resistor 5, and a second indicator 13 is connected to its output. The control input of the unit 12 is connected to one of the outputs of the synchronizer 9. The device operates as follows. From the synchronizer 9, control gates of different durations (Fig. 2) arrive at the control inputs of switches 2 and 3, source 8, and blocks 10 and 12, specifying the sequence of operation and the duration of the periods of the remaining elements. The source 8 excludes a constant measuring current, the polarity of which can vary under the de-synchronizer 9 (Fig. 2i1). This current, flowing through the resistor 7, creates a voltage drop across it, measured with the help of block 10 and indicator 11. To eliminate any influence of the polarization current on the result of the resistance measurement; electrochemical resistor, i.e. to achieve better measurement accuracy, the voltage drop across resistor 7 is measured during periods of interruption of the polarization current (Fig. 2.2). Interrupts are performed using switches 2 and 3, opamp 4 and resistor 5 in the following way. Under the action of the synchronizer 9, the output of amplifier 4 is connected via switch 3 directly to its inverting input, as well as through a resistor 5 and switch 2 to a non-inverting input, while the auxiliary electrode of cell 6 is connected to the non-inverting input of amplifier 4. Due to deep negative feedback The output of amplifier 4 is set to exactly the same voltage as on the auxiliary electrode of cell 6. Therefore, the polarization current does not flow through the resistor .5, which is sensitive The element of this circuit and, therefore, through the cell resistor 7. During the interruption of the polarization current, the unit 10 operates in the sampling mode (Fig. 2.3) and the indicator 11 displays the result of the resistance measurement, not distorted by the polarization current, corresponding to a specific voltage reference electrode (Fig. 2.4).

During the period of passage of the polarization current through cell 6 from source 1 switch 2 to the non-inverter input, amplifier 4 receives a polarization voltage, and the inverter input receives voltage through the switch 3 through the polarization current on the reference electrode the required voltage value is set. During this period, unit 10 operates in storage mode, And at its output there is a voltage obtained during the period of interruption of the polarization current. After the end of the period of passing the polarization current (polarization period), the interruption period begins again (the measurement period of the resistance of the electrochemical resistor). Moreover, at the beginning of the polarization period, the voltage at the output of amplifier 4 is equal to the voltage on the auxiliary electrode of cell 6 and begins to change precisely from the value of this voltage, as a result of which cell 6 eliminates the appearance of unwanted current surges.

When measuring the resistance of an electrochemical resistor, one of the test parameters is a polarization current, which can be measured using the proposed device. The resistor 5 connected in series with the cell 6 can serve as the element on which the voltage proportional to the current is polarized. However, the voltage drop across the resistor 5 cannot be directly used for measurement and display purposes (for example, by means of a coordinate graph), since It is due to the interruption that a pulsed polarization current flows which creates a pulsed voltage drop, which leads to an error in measuring the polarization current. By means of a block 12 connected in parallel with the terminals of the resistor 5, a constant voltage proportional to the polarization current is formed. During the periods of polarization, unit 12 operates in the sampling mode (Fig. 2.5) and at its output there is a voltage proportional to the polarization current (Fig. 2.6), which is indicated by the indicator 13. During periods of interruption of the polarization current, unit 12 operates in the stopping mode, and the indicator 13 displays the voltage value measured during the polarization period. Thus, the device allows the formation of a constant voltage proportional to the polarization current.

The proposed device improves the accuracy of measuring the resistance of an electrochemical resistor and provides a change in the polarization current.

Story cheating if measure neither / fb

HOW current

CmpoStti polarization current interruption2

Suffering u riepf nor soprop7iv laziness

Bbfxo & Hoe nlr fKBHuc SenZ

Polarization current measurement

Output voltage of circuit 7b

(puz.2

Claims (2)

1. DEVICE FOR MEASURING RESISTANCE OF ELECTROCHEMICAL RESISTORS, containing a three-electrode electrochemical cell, one of the electrodes of which is an electrochemical resistor, an adjustable polarization voltage source, the first indicator, characterized in that, in order to improve the measurement accuracy, two controllable switches are inserted into it, 'operational an amplifier, a resistor, a controlled source of measuring current, the first sampling and storage unit, a synchronizer, the output of an adjustable voltage source being Iarization is connected to the first information input of the first switch, the output of which is connected to a non-inverting input of the operational amplifier, the output of which is connected through a resistor to the auxiliary electrode of the electrochemical cell and to the second information input of the first switch, as well as directly to the first information input of the second switch, which has a second information the input is connected to the reference electrode of the electrochemical cell, and the output is connected to inverters. by the operating amplifier input, the electrochemical resistor is connected to a controlled measuring current source and to the first sampling and storage unit 5, and the control inputs of both switches, measuring current source and the first sampling and storage unit are connected to the synchronizer outputs, and to the output of the first sampling and storage unit the first indicator is connected. 2. The device according to π. 1, it is necessary that, in order to expand the functionality, namely, to measure the polarization current and generate a constant voltage proportional to this current, a second sampling and storage unit is introduced, connected in parallel to the resistor terminals moreover, the control input of the second sampling and storage unit is connected to one of the outputs of the synchronizer, and a second indicator is connected to its output. 1,148,002 A 1 1148 002 2