RU2084006C1 - Device for analysis of waters in boreholes - Google Patents

Abstract

FIELD: remote measurement of parameters of aqueous medium, in particular, measurement of temperature, hydrostatic pressure, conductivity, pH-value, redox potential Eh, content of dissolved oxygen, concentrations of different ions of aqueous medium in boreholes. SUBSTANCE: device uses a submergible probe and a surface unit connected through a borehole cable; the submergible probe has a tests forming unit, and the surface unit uses an identification unit, computer and a parameter storage unit. EFFECT: enhanced accuracy of measurements and expanded functional capabilities. 2 cl

Description

 The invention relates to devices for remote measurement of the parameters of the aquatic environment, in particular, for measuring temperature, hydrostatic pressure, electrical conductivity, pH, redox potential Eh, dissolved oxygen, concentrations of various ions of the aquatic environment in the wells.

 A device for studying terminal water in wells is known, consisting of an immersion probe containing sensors, a multichannel transducer and a voltage stabilizer, a ground block containing a current source, a receiving transducer, an indication and recording device, a single-core logging cable connecting the immersion probe to the ground block.

 However, the device does not allow accurate measurements of such parameters of the aquatic environment as temperature, hydrostatic pressure, electrical conductivity, because upon receipt of the measurement results, nonlinear individual transformation functions of the corresponding measuring channels and their changes in time under the influence of destabilizing factors (measurements of ambient temperature, voltage, etc.) are not taken into account. In addition, in the specified device there is no possibility of changing the set of measured water parameters (for example, in case of differences in the composition of aqueous solutions in different wells) and automatically taking into account the individual parameters of interchangeable sensors.

 In a device consisting of an immersion probe containing a sensor unit connected to the input of a transmitting multichannel converter connected to a voltage stabilizer, a ground unit containing a current source, the input of which is connected to the output of the power supply, and the output to the input of the receiving converter, and an indication device and of registration of a single-core logging cable connecting the voltage stabilizer of the immersion probe to the output of the current stabilizer of the ground unit, a test generation unit has been introduced, the outputs of which By connecting the other inputs of the transmitting multi-channel transmitter, the identification section, the input of which is connected to the output of the receiving transducer, and the computing device, one input of which is connected to the output of the receiving transducer with different output identification unit, and the output from the display device and registration.

 In addition, a parameter storage unit connected to a computing device is additionally introduced into the device.

 Improving the accuracy of measurements and expanding the functionality (expanding the list of water parameters measured with high accuracy, including such parameters as temperature, hydrostatic pressure, electrical conductivity, hydrogen pH, redox potential Eh, dissolved oxygen content, concentration of nitrate nitrogen, ammonium ions nitrogen, sodium, sulfide sulfur, etc.) is achieved through additional measurements of specially formed test values, creating at the current moment using the identification unit and using these parameters to calculate the values of all measured quantities using a computing device. In addition, the expansion of functionality is achieved through the introduction of a storage unit for the parameters of all the sensors used, which makes it possible to quickly change the set of measured values.

 A device for researching water in wells is shown in the drawing.

 The immersion probe is a housing 2, on which the sensors 1 are installed and in which the test generation unit 3, the multichannel transmitting transducer 4 and the voltage stabilizer 5 are placed. The probe is connected to the ground unit by a single-core armored logging cable 6.

 The ground unit includes a current stabilizer 7, a power supply 8, a receiving transducer 9, a computing device 10, an identification unit 11, a parameter storage unit 12, an indication and recording device 13.

In a manufactured instance of a device for studying water in wells, an immersion probe has a titanium case with a diameter of 65 mm. The set of sensors used includes sensors of temperature, hydrostatic pressure, electrical conductivity, dissolved oxygen, pH, Eh electrodes, comparisons, various ion-selective electrodes (NO ₃ , NH ₄ , Na, H ₂ S, Cu, etc.). The device has 8 measuring channels (i.e., 8 parameters of the aqueous medium are simultaneously measured), including channels of temperature, hydrostatic pressure, electrical conductivity, dissolved oxygen and 4 potentiometric channels, each of which can be used to measure pH, Eh and concentrations various ions using ion-selective electrodes.

 A low inertia platinum resistance thermoconverter was used as a temperature sensor, a silicon-sapphire type pressure transducer was used as a pressure sensor, a four-electrode conductometric cell was used as a conductivity sensor, a Clark sensor was used as a dissolved oxygen sensor, and ion-selective sensors were used as various oxygen concentration sensors electrodes.

 In a multi-channel transmitting converter, the output signal of each sensor is converted into a unified signal by a pulse train with frequency modulation. In this case, voltage amplifiers with a high input resistance are used at the inputs of potentiometric channels, and a current to voltage converter is used at the input of the dissolved oxygen channel. Next, the frequency-modulated signal is converted into a digital code by means of a noise-immune converter with averaging.

 The digital code from the output of the multi-channel transmitting converter is supplied to a voltage stabilizer, which provides not only the electrical power of the immersion probe, but also serial transmission of the codes via a single-core logging cable. The conversion of the signals of various sensors into a code and the transmission of these codes by cable are also performed sequentially.

 In addition to alternately polling sensors, a multichannel transmitting transducer also polls the outputs of the test generation unit.

 For different measuring channels, tests are formed in different ways: for channels with resistive sensors (temperature, pressure, electrical conductivity), precision resistors are used to form tests, and precision voltage regulators are used for hydrochemical channels. The number of tests for different measuring channels is different and equal to the number of parameters of the mathematical model used for the conversion function of the measuring channel: for the linear model 2 tests, for the nonlinear model (power polynomial of the second order) 3 tests. Linear models of the conversion function are used for hydrochemical channels, and nonlinear models for channels of temperature, pressure, and electrical conductivity. The need to use non-linear models is determined by wide ranges of variation of the indicated measured values in the wells and high requirements for the accuracy of their measurements.

 Electrical power for the immersion probe is carried out from the power supply unit of the ground unit through a current stabilizer, which provides the best (compared to the power supply from the voltage source) mode of operation of the electronic devices of the probe when the electrical resistance of the wireline changes.

 The receiving converter separates the information signal coming through the cable from the supply voltage and converts it to a form convenient for input into the computing device and the identification unit.

 The identification unit uses the results of signal transformations of all sensors and tests and, taking into account the type of mathematical model of the conversion function of each measuring channel, determines the values of the parameters of this function for each measuring channel at the current time by solving the corresponding system of equations. The obtained real parameters of the measurement channel conversion functions are entered into a computing device, which, using these parameters, the corresponding mathematical models of the measuring channels and the individual parameters of the sensors, calculates the values of all measured values.

 The calculated values of the measured quantities are output to the display and registration device in the form of named numbers in units of measurement of the corresponding quantities.

 Thus, taking into account the individual (linear and nonlinear) conversion functions of all measuring channels, determining the actual parameters of these functions at the time of measurement and taking into account the individual parameters of the sensors made it possible to ensure high measurement accuracy, in particular, to refuse thermostating of a multi-channel transmitting transducer in an immersion probe, which simplified the design and reduced the cost of the device.

 Due to the fact that when researching various wells there is a need to change the set of measured values, the device provides the ability to quickly replace hydrochemical sensors (pH, Eh, ion-selective electrodes). For this purpose, a parameter storage unit connected to a computing device is additionally introduced into the ground unit. The parameters storage unit stores individual parameters of all sensors that can be used in the device. The operator installs the necessary sensors in the immersion probe and enters into the computing device information on which measuring channel which sensor is applicable. When determining the values of the measured values, the computing device automatically uses the individual parameters of the respective sensors stored in the parameter storage unit. The stored values of the parameters of the sensors are changed automatically during calibration.

 To ensure high accuracy of measurements, the device provides various types of calibrations: full and abbreviated. Full calibration is performed for all sensors and measuring channels in the laboratory using the necessary technical means (an exemplary water thermostat, an exemplary pressure gauge, exemplary solutions, etc.).

 Abbreviated calibrations are performed only for hydrochemical measuring channels in the field and allow, without using sophisticated special equipment, to determine the least stable parameters of hydrochemical sensors. So a complete calibration of the pH of the electrode and ion-selective electrodes allows using 3 sample solutions to determine 3 parameters of the conversion function of each electrode (sensitivity and two coordinates of the isopotential point). With an abbreviated calibration, part of the parameters of the hydrochemical sensors is determined by calibration in the field, and for the remaining parameters, the values obtained with a full calibration are used.

 Abbreviated calibration has two varieties: two-parameter and one-parameter. A two-parameter reduced calibration of hydrochemical sensors is carried out using two standard solutions, and a one-parameter one by one standard solution, but the probe with electrodes immersed in the standard solution is lowered into the well to the same depth at which the measurements are made, and the standard solution is determined from the environment by a flexible membrane .

 With any type of calibration, the parameters of the sensors and measuring channels are determined automatically and recorded in the parameter storage unit.

The manufactured instance of the device has passed laboratory tests and field tests at various wells. Metrological studies conducted in the Volga Center for Standardization and Metrology (Samara), showed that the device has the following measurement errors: temperature 0.01 ^o C in the range 0-60 ^o C; hydrostatic pressure of 0.15% (reduced error); conductivity 0.0005 S / m in the range of 0.005-1 S / s; the dissolved oxygen content of 0.3 mg / l in the range of 0-20 mg / l; Eh 1 mV in the range 500 + 1800 mV; pH 0.05 units pH activities of various ions 0.05-0.1 log units

 Natural tests and production operation of the device in wells in the Chelyabinsk region showed that, compared with the known devices for studying water in wells, it has wider functional capabilities, higher measurement accuracy, ease of measurement and calibration, and the speed of obtaining and processing measurement information.

 The proposed device is intended for well research by hydrogeochemical logging, for environmental monitoring of groundwater in wells, and can also be used to study the aquatic environment in open waters.

Claims (2)

 1. Device for researching water in wells, consisting of an immersion probe containing a block of sensors connected to the input of a transmitting multichannel converter connected to a voltage stabilizer, a ground block containing a current source, the input of which is connected to the output of the power supply, and the output to the input of the receiving the Converter, and a display and registration device, a single-core logging cable connecting the voltage regulator of the immersion probe with the output of the current stabilizer of the ground unit, characterized in that the immersion probe contains a test generation unit whose outputs are connected to other inputs of the transmitting multichannel converter, and the ground unit contains an identification unit whose input is connected to the output of the receiving transducer, and a computing device, one input of which is connected to the output of the receiving transducer, and the other with the output of the block identification, and output with a display and registration device.  2. The device according to claim 1, characterized in that it further comprises a parameter storage unit connected to the computing device.