SU1756812A1 - Device for measuring corrosion activity of soil - Google Patents

Abstract

Use: instrumentation technology, in particular to determine the corrosiveness of the soil. SUMMARY OF THE INVENTION: The device comprises a master oscillator 1, a pulse shaper 2, a first switch 3, a direct current amplifier 4, a measuring unit 5, a first current generator 6, a summing amplifier 7, a sampling-storage unit 8, a second current generator 9, a specific sensor 10 resistance, the second switch 11, the reference resistor 12, the control unit 13, the analog-digital converter 14 and the indicator 15. 2 Il, 2 tab.

Description

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The invention relates to a measuring and control technique and is intended to determine the corrosiveness of a soil when designing protection of pipelines laid in the ground in order to identify sections of pipelines that are in a zone of corrosive danger; caused by the aggressiveness of the soil or the influence of stray currents.

A current and polarization potential meter is known, comprising a two-electrode sensor, a pulse generator connected in series, a switch, a DC amplifier whose output is connected to the input of a recording device, for example, a milliammeter, and connected to the first input of the switch, the second input of which is connected sensor output.

The disadvantage of the known meter is the laboriousness and complexity of the measurement process, the low accuracy of the measurement result.

The closest to the technical essence is a device for measuring the corrosivity of a soil, which contains a master oscillator, a first switch, a DC amplifier, a measuring unit and an indicator.

A disadvantage of this device is the laboriousness, the complexity of the measurement process, and the low accuracy of the measurement result.

The aim of the invention is to improve the measurement accuracy.

This goal is achieved by the fact that the device for measuring the corrosiveness of the soil, which contains the master oscillator, the first switch, the DC amplifier, the measuring unit, and the indicator, the first gathering of the first switch connected to the first output of the measuring unit, the first input of which is connected to the first output of the first switch, the second output of which is connected to the input of the DC amplifier, is equipped with a pulse shaper, the first and second current generators, a summing amplifier, a sampling unit - storage, a resistivity sensor, second switches, a reference resistor, a control unit and an analog-digital converter, the output of the master oscillator connected to the input of the pulse former, to the first input of the second switch and the first input of the first current generator, the input sensor of the specific resistance is connected to the first output of the first current generator, the second input of which is connected to the resistivity sensor, the second output of the first generator

current is connected to the second input of the second switch, the output of which is connected to the first input of the control unit, the output of the measuring unit is shunted by the reference register, to the terminals of which the second input of the control unit is connected, the output of the pulse former is connected to the second input of the first switch, the third input and the first input of the unit sample storage is excluded from the first output of the control unit, the output of the DC amplifier is connected to the second input of the sample-storage unit and one of the inputs of the summing amplifier, you the path of the sampling-storage unit through a series-connected summing amplifier and the second current generator is connected to the fourth input of the first switch, and the output of the control unit through an analog-to-digital converter is connected to the indicator.

FIG. 1 is a block diagram of a device for measuring the corrosivity of a soil; in fig. 2 is a schematic diagram of the execution of blocks entering the device.

The device contains a master oscillator 1, a pulse shaper 2, a first switch 3, a DC amplifier 4, a measuring unit 5, a first current generator b, a summing amplifier 7, a sampling-storage unit 8, a second current generator 9, a resistivity sensor 10, a second the switch 11, the reference resistor 12, the control unit 13, the analog-to-digital converter (ADC) 14, the indicator 15.

The measuring unit 5 consists of a working electrode 16, a reference electrode 17 and an auxiliary electrode 18.

The pulse shaper 2 consists of a capacitor 19 and a resistor 20.

The control unit 13 consists of switches 21 and 22.

Sampling-storage unit 8 consists of buffer amplifiers 23 and 24, a transistor 25, a resistor 26, a relay 27 and a capacitor 28.

The current generator 6 consists of a resistive bridge made on resistors 29–32 and an electronic switch 33.

The device works as follows.

I. The mode of measurement of the specific current of soil polarization.

For measurements in this mode, a measuring unit 5 is used to measure the specific current of polarization of the soil. Work 16 and auxiliary 18 electrodes are mounted on opposite sides of the measuring cell in the center. Then the cell is filled with the test soil. Top in

the ground is set by the reference electrode 17. The electrodes 16 and 17 are connected respectively to the inputs A and B of the switch 3, and the electrode 18 to the potential-free bus through a resistor 12, B the initial moment of time the switch 21 of the control unit 13 is set to d the position of Corrosion. The voltage of the logical unit is fed to the switch 3. Pulses with a frequency of 200 Hz from the master oscillator 1 are fed to a PC circuit 20 and 19 with a constant time of 0.65 ms. These pulses arrive at the second input of switch 3. Switch 3, when a logical unit is applied to the first input and closes to the second input, closes, while acting on the second one to a logical unit, enter A, B respectively with outputs A2, B2. Therefore, the amplifier 4 input the direct current through the input B and output B2 of the switch 3 is connected to the reference electrode 17, and the working electrode 16 to the potential-free bus through the input A and the output A2 of the switch 3. The DC amplifier 4 measures the corrosion potential between the auxiliary electrode 18 and the elec- By reference electrode 17 of the measuring unit 5. This potential from the output of the DC 4 amplifier is fed to the input of the sample-storage unit 8, which is in the Sampling mode, since the second input of the sample-storage unit 8 is fed to the controllers through the switch 21 of the control unit 13 the voltage of the logical unit, after 10 minutes, the switch 21 of the control unit 13 is set to the Polarization position. In this case, the logical zero voltage through the switch 21 of the control unit 13 is fed to the first input of the switch 3.

The current generator 9 through the input A and the output A3 of the switch 3 is connected to the working electrode 16 during the operation of a logic zero at the second input of the switch 3. The polarization current flows through the working 16 and auxiliary 18 electrodes and the reference resistor 12 to the zero potential bus.

At the moments of action at the second input of the switching unit 3 of the logical unit, the comparison electric 17 is connected to the DC amplifier A, and the working electrode 16 to the zero potential bus. The polarization circuit is broken.

The second control input of the sampling-storage unit 8 is supplied with a logic zero voltage and the sampling-storage unit 8 is in the Storage mode. At the same time, at its output, the voltage of the corrosion voltage measured and memorized before the activation of the Polarization mode (Uic.p.). This voltage goes to the first input.

The summing amplifier 7. To the second input of the summing amplifier 7, the current value of the voltage on the reference electrode 17 is fed through the amplifier 4 constant

current and switch 3.

The summing amplifier 7 controls the current of the current generator 9. Since the gain of the summing amplifier 9 is 1000, then even with a small difference

between its input voltages, the gigantic current generator 9 is limited and is 23A.

The voltage at the second input of summing amplifier 7, i.e. present value

the voltage across the reference electrode 17 (Up) is inversely proportional to the magnitude of the polarization current. Therefore, as the polarization current flows, the voltage difference at the inputs of summing amplifier 7 decreases and tends to zero.

In this case, the current of the current generator 9 begins to be determined by the magnitude of the voltage difference at the inputs of the summing amplifier 7, i.e. 1 Up-Vic.p, 1

Consequently, the current generator 9 maintains such a polarization current that the spikes on the reference electrode 17 are approximately equal to the voltage at the output of the sampling-storage unit 8, i.e. the corrosion potential of the working electrode is 16 minus 100 mV. The shift by 100 mV is carried out in the buffer amplifier 24 of the sampling-storage unit 8.

1 The polarization current flows through the reference resistor 12 to the zero potential bus. The voltage from this resistor through the switch 22 is fed to the ADC 14 and then to the generator 15.

Thus, indicator 15 displays the current value of the polarization current.

Then on the table. 1, the corrosivity of the soil is determined.

Table 1

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I. Measurement mode of soil resistivity,

Seeing that the electrodes placed in the electrolyte solution, the properties of which have real soils, are polarized when DC current flows, and the resulting potential difference distorts the resistance values

measured by the traditional method, it is necessary to measure the resistance on alternating current, moreover, such that the magnitude and duration of the positive half-period would be negative.

For measurements in this mode, a second sensor 10 is used to measure the resistivity of the soil. The two electrodes 34 and 35 are mounted on opposite sides of the resistivity cell. The measuring cell is then filled with the test soil, and the outputs of the electrodes 34 and 35 are connected between the resistor 30 and the zero potential bus of block 9. The stabilized voltages 1 + 5V and -5V from the power supply unit to the electronic switch 33 of the second current generator 9. The operation of the electronic switch 33 is controlled by pulses with a frequency of 200 Hz and a duty cycle equal to one from the master oscillator 1. At the output of the switch 33, an alternating voltage with an amplitude of 10 V of rectangular shape and a duty cycle equal to one is obtained. This voltage is applied to the shoulders of a bridge formed by the reference resistors 31 and 32.29 and 30 connected in series with the sensor 10, and then to the switch 11, which is controlled by pulses 200 Hz from the master oscillator 1. The rectified alternating voltage from the output the switch 11 through the contacts of the switch 22 of the control unit 13 is fed to the A / D converter 14 and then to the indicator 15.

Thus, the indicator 15 displays the value of the current of the alternator 9, where R is the resistance of the soil of the resistivity measuring cell or

U-1xpxp

where p is the soil resistivity;

S is the area of the plate;

L is the distance between the sensor plates.

Accordingly, by choosing the values of S and L, indications on the resistivity of the soil are obtained on the indicator.

Then on the table. 2 determines the corrosivity of the soil.

table 2

As a result of comparing the values of the corrosivity of the soil, obtained in both modes, they are chosen as the maximum of them.

This device provides high accuracy of the measurement result, reduces labor intensity and greatly simplifies the measurement process.

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Claims (1)

Invention Formula A device for measuring the corrosivity of a soil, comprising a master oscillator, a first switch, DC amplifier, measuring unit and indicator, the first input of the first switch is connected f by the first output of the measuring unit, the first input of which is connected to the first output The first switch, the second output of which is connected to the input of a DC amplifier, characterized in that, in order to improve the measurement accuracy, it is equipped with a pulse shaper, a first and second current generators, a summing amplifier, a sample-storage unit, a resistivity sensor, a second switch , a reference resistor, a control unit and an analog-digital converter, the output of the master oscillator is connected to the input of the pulse former, to the first input of the second switch and the first input of the transducer Vågå alternator sensor input The resistivity is connected to the first output of the first current generator, the second input of which is connected to the resistivity sensor, the second output of the first current generator is connected to the second input of the second switch, the output of which is connected to the first input of the control unit, the output of the measuring unit is shunted with a reference resistor, to the terminals of which connected to the second input unit control, the output of the pulse generator is connected to the second input of the first switch, the third input of which and the first input of the sampling-storage unit are connected to the first output of the control unit, the output the DC amplifier is connected to the second input of the sampling-storage unit and one input of the summing amplifier; the output of the sampling-storage unit is connected via series-connected summing the amplifier and the second current generator are connected to the fourth input of the first commutator, and the output of the control unit is connected via an analog-digital converter to the indicator. thirty n h and W - ft "4