RU2769095C1 - Electrical conductivity variation meter - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: invention relates to measurement equipment and can be used for continuous measurement of electrical conductivity, mineralization and temperature in natural and man-made medium, accumulation and output of digital measurement results to a system for monitoring the state of the environment. Electric conductivity variation meter includes housing (1), inside of which there are inductive conductivity transducer (3), coupling coil (4), temperature sensor (7), calibration unit (5), conductivity measurement unit (6), temperature measurement unit (8), real-time interface unit (9), memory unit (10), electric conductivity values temperature correction unit (11), comparator unit (12), notification unit (13), lightning protection terminal (14), control processor (15). Conductivity measurement unit (6) is connected to the output of the inductive conductivity transducer (3), which is connected to calibration unit (5) by means of communication loop (4), the temperature measurement unit (8) is connected to temperature sensor (7), a real-time interface unit (9) and input of memory unit (10), input of memory unit (10) is connected to output of conductivity measurement unit (6), two outputs of memory unit (10) are connected to inputs of temperature correction unit (11), and the output of the temperature correction unit (11) is connected to the input of comparator unit (12), the output of which is connected to the input of warning unit (13), the output of which is connected to the input of the lightning protection terminal (14), control processor (15) is connected to the inputs of calibration unit (5) and two-way communication with real-time interface unit (9), memory unit (10), temperature correction unit (11), comparator unit (12) and notification unit (13).

EFFECT: high accuracy of measuring electrical conductivity during continuous operation of the meter of variations of salinity (electrical conductivity) as part of a monitoring system.

3 cl, 3 dwg

Description

The invention relates to the field of measuring technology and can be used for continuous measurement of electrical conductivity, salinity and temperature in natural and industrial environments, accumulation and output of digital measurement results to the environmental monitoring system during surveys, construction and operation of facilities.

A device is known (RU No. 2365909, 27.08.2009), containing a generator, the output of which is connected to the input of the switch and to the reference input of the synchronous detector, to the output of which the indication unit is connected, a conductometric transducer, including the first core with the first winding, the second core with the second and third windings, the first coupling element, inside of which there is a cavity filled with the test or sample liquid, and which covers the first and second cores, the third core with the fourth winding, the second coupling element, inside which there is a cavity filled with the exemplary liquid, and which covers the third core , wherein the first terminals of the first, second, third and fourth windings are connected to a common bus, the second terminal of the first winding is connected to the first output of the switch, the second terminal of the third winding is connected to the input of the amplifier, the output of which is connected to the signal input of the synchronous detector, a resistor characterized in that that in order to improve accuracy and measurements, the fourth core with the fifth and sixth windings, covered by the second coupling element, the second switch and the "code-voltage" converter are introduced, the first outputs of the fifth and sixth windings are connected to a common bus, the second output of the first switch is connected to the second output of the fourth winding, the power input the "code-voltage" converter is connected to the output of the generator, and the output of the "code-voltage" converter is connected through a resistor to the input of the second switch, the first output of which is connected to the second output of the second winding, the second output of the second switch is connected to the second output of the fifth winding, the second output the sixth winding is connected to the second input of the amplifier.

The disadvantage of the known device is the impossibility of its use as part of a monitoring system during surveys, construction and operation of structures, as it is a laboratory device used in metrology as an exemplary measuring instrument for verification and calibration of measuring instruments of lower accuracy, as well as for certification of standard solutions .

The problem to be solved by the claimed invention is the development of an electrical conductivity variation meter, which will eliminate the disadvantages of the prior art.

The technical result, to which the claimed invention is directed, is to increase the accuracy of electrical conductivity measurements during continuous operation of the salinity (electrical conductivity) variation meter as part of the monitoring system.

The specified technical result, to which the claimed technical solution is directed, is achieved due to the fact that the electrical conductivity variation meter includes a housing inside which an inductive conductivity transducer, a coupling coil, a temperature sensor, a calibration unit, a conductivity measurement unit, a temperature measurement unit, an interface unit of a real time block, a memory block, a block for temperature correction of electrical conductivity values, a comparison block, a notification block, a lightning protection terminal, a control processor, while the conductivity measurement block is connected to the output of an inductive conductivity transducer, which is connected to the calibration block via a communication loop, the temperature measurement block is connected to the sensor temperature, a real-time interface unit and the input of the memory unit, the input of the memory unit is connected to the output of the conductivity measurement unit, two outputs of the memory unit are connected to the inputs of the temperature correction unit, and the output of the temperature correction unit is connected to the input of the comparison unit, the output of which is connected to the input of the notification unit, the output of which is connected to the input of the lightning protection terminal, the control processor is connected to the inputs of the calibration unit and two-way communication with the real-time interface unit, the memory unit, the temperature correction unit, the comparison unit and the block alerts.

The inductive conductivity transducer contains receiving and transmitting coils.

The output of the lightning protection terminal is additionally connected to the server of the monitoring system through a system of auxiliary units, which contains a junction box, a backup battery, an AC/DC converter, an unauthorized access sensor and a data acquisition-transmission unit.

Brief description of the drawings.

In FIG. 1 shows a structural and functional diagram of the electrical conductivity variation meter.

In FIG. 2 shows a block diagram of the structural elements of the electrical conductivity variation meter responsible for electronic calibration.

In FIG. 3 shows a general view of the electrical conductivity variation meter (in section).

Meter of electrical conductivity (salinity) variations (Fig. 1-3), contains a housing (1), inside which are placed an inductive conductivity transducer (3), a connection coil (4) (calibration), a temperature sensor (7), a calibration unit (5) , conductivity measurement unit (6), temperature measurement unit (8), real-time interface unit (9), memory unit (10), temperature correction unit (11) of electrical conductivity (salinity) values, comparison unit (12) with threshold values of electrical conductivity (salinity), warning block (13), lightning protection terminal (14), control processor (15).

The output of the inductive conductivity transducer (3) is connected to the conductivity measurement unit (6), from the calibration unit (5) the connection coil (4) (calibration) goes to the inductive conductivity transducer (3). The temperature sensor (7) is connected to the temperature measurement unit (8). The real-time interface unit (9) is connected to the temperature measurement unit (8) and to the conductivity measurement unit (6), two inputs of the calibration unit (5) are connected to two outputs of the control processor (15). The input of the memory block (10) is connected to the output of the conductivity measurement block (6), and the two outputs of the memory block (10) are connected to the inputs of the temperature correction block (11) of conductivity (salinity) values. The output of the block for temperature correction (11) of conductivity (salinity) values is connected to the input of the block for comparison (12) with threshold values (conductivity) of salinity, the output of which is connected to the input of the warning block (13), the output of which is connected to the input of the lightning protection terminal (14). The control processor (15) is connected by two-way communication with a real-time interface unit (9), a memory unit (10), a temperature correction unit (11), a comparison unit (12) with threshold values, and an alert unit (13). The output of the lightning protection terminal (14) through the system of auxiliary units located outside the well (21), which contains a junction box (16), a backup battery (17), an AC / DC converter (18), an unauthorized access sensor (19) and a collection unit - data transmission (20) is connected to the monitoring system server.

The electrical conductivity (salinity) variation meter works as follows. Block (3) with block (6) measures the electrical conductivity (salinity) linked to the current value of time using the real-time interface block (9). Block (7) and block (8) measure the temperature, also tied to the current value of time using the real-time interface block (9). Signals about the measured values of electrical conductivity (salinity) and temperature are received respectively on the first and second inputs of the memory block (10). From the memory block (10), both signal values are fed to the first and second inputs of the block (11) for temperature correction of the electrical conductivity (salinity) value. Block (11) analyzes and temperature corrects the measured value of electrical conductivity (salinity) depending on the measured temperature. The corrected values of electrical conductivity (salinity) enter the block (12), where they are compared with the threshold values stored in its memory. When the threshold value is exceeded, the notification unit (13) receives an alarm signal, which, after passing through the lightning protection unit (14), junction box (16), data collection and transmission unit (20), which are part of the equipment located outside the well, together with the value measured electrical conductivity (salinity) is sent to the server of the monitoring system.

Blocks for temperature measurement (8), real-time interface (9), memory (10), temperature correction of values (11) and comparison with threshold values (12) ensure that the influence of changes in the ambient temperature is taken into account, which reduces the measurement error of electrical conductivity (salinity). The part of the device responsible for electronic calibration consists of a calibration unit (5), a coupling coil (4), which passes through the receiving and transmitting coils of the inductive conductivity transducer (3). Outside the calibration process, the communication loop (4) is open. The calibration is controlled using the On signals. S1 and On S2 generated by the control processor (15).

Calibration of the electrical conductivity meter is performed using a 2-stage switching of exemplary resistors that form the current through the calibration loop of the connection (4), covering the receiving and transmitting coils (inductances).

At its core, the electrical conductivity will depend on the amount of salt present in the medium under study.

The control processor (15) sends the control command S1 to the calibration unit (5), which closes the first electronic switch. A current flows through the connection loop (4), limited by the resistance R1. This measures the conductivity (salinity) reading S1. After that, the control signal S1 is removed and the calibration unit (5) receives the control signal S2, which closes the second electronic switch. In the connection coil (4), a current flows, limited by the resistance R2. In this case, the electrical conductivity (salinity) S2 is measured.

Processing of indications of the calibration process is as follows

S0 - the value of the measured electrical conductivity (salinity) in the environment without calibration;

S1=S0+Sk1 - the value of the measured electrical conductivity (salinity) in the environment in the first calibration state;

S2=S0+Sk2 - the value of the measured electrical conductivity (salinity) in the medium in the second calibration state

ΔSk is defined as the difference between the values of the measured electrical conductivity (salinity):

ΔSk=S1-S2=Sk1-Sk2

ΔSк - this is the calibration constant, independent of the electrical conductivity (salinity) of the medium S0, i.e. S0 does not affect the calibration process, which can be carried out without removing the instrument from the controlled environment.

The stability of the calibration constant characterizes the stability of the metrological characteristics of the instrument.

The claimed device can be used in automated systems for monitoring dangerous geological processes for the purpose of early warning of the onset of an event that can lead to catastrophic consequences, and taking the necessary measures to reduce the amount of possible damage from such events.

It can be used to study the hydrophysical properties of water in the shelf zones of the ocean and in wells in the permafrost zone.

Claims (3)

1. An electrical conductivity variation meter, including a housing containing an inductive conductivity transducer, a coupling coil, a temperature sensor, a calibration unit, a conductivity measurement unit, a temperature measurement unit, a real-time interface unit, a memory unit, a unit for temperature correction of electrical conductivity values, a comparison unit, notification unit, lightning protection terminal, control processor, wherein the conductivity measurement unit is connected to the output of the inductive conductivity transducer, which is connected to the calibration unit via a connection loop, the temperature measurement unit is connected to the temperature sensor, the real-time interface unit and the input of the memory unit, the input of the memory unit connected to the output of the conductivity measurement unit, two outputs of the memory unit are connected to the inputs of the temperature correction unit, and the output of the temperature correction unit is connected to the input of the comparison unit, the output of which is connected to the input of the notification unit, the output of which is connected to the input ohm of the lightning protection terminal, the control processor is connected to the inputs of the calibration unit and two-way communication with the real-time interface unit, memory unit, temperature correction unit, comparison unit and notification unit. 2. The electrical conductivity variation meter according to claim 1, wherein the inductive conductivity transducer comprises receiving and transmitting coils. 3. The electrical conductivity variation meter according to claim 1, in which the output of the lightning protection terminal is additionally connected to the server of the monitoring system through a system of auxiliary units, which contains a junction box, a backup battery, an AC / DC converter, an unauthorized access sensor and a data collection and transmission unit.

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