RU218823U1 - MULTIELECTRODE MODULE FOR SOLUTION ACID ANALYSIS - Google Patents

Abstract

The utility model relates to potentiometric measurements of the concentration of ions in solutions (of the medium under study), namely, to a comparative pH electrode, a reference electrode and a redox potential electrode, operating in conjunction with a measuring device, and can be used to analyze the acidity of solutions, in particular for analysis of the ionic composition of the drilling mud and fluid.

The technical result is an increase in the accuracy of the electrochemical analysis of the ionic composition of the medium under study during hydrodynamic logging and testing of formations.

Essence of the utility model: a multi-electrode module for analysis of the acidity of solutions contains a measuring chamber in which a measuring electrode, a reference electrode and a redox potential electrode are placed, a measuring device with a cover, made in the form of an electronic board with a microprocessor, while the measuring chamber includes a sealing unit, a glass drop, a chamber with silicone oil, in which there is a channel for pouring silicone oil, a piston compensator, and a glass flask located in the lower part of the measuring chamber.

Description

The utility model relates to potentiometric measurements of the concentration of ions in solutions (of the medium under study), namely, to a comparative pH electrode, a reference electrode and an redox potential (ORP) electrode, working together with a measuring device, and can be used to analyze the acidity of solutions, in particular for the analysis of the ionic composition of the drilling mud and fluid.

Analysis (electrochemical) of the ionic composition of the drilling mud and fluid during hydrodynamic logging and testing of formations is based on measuring the electromotive force (EMF) of a galvanic cell under conditions of high temperature up to 90 C and high pressure up to 100 MPa.

An express analyzer of liquid media is known (RF patent No. 2112974, G01N 33/04, G01N 27/22, published: 06/10/1998), containing measuring ion-selective electrodes combined in one housing and an auxiliary silver chloride reference electrode, a high-resistance converter and a temperature sensor, and silver chloride the half-element of the auxiliary reference electrode is immersed in a polymer electrolyte of a KCl solution, and the high-resistance converter is equipped with a built-in programmable controller that calculates the values of titratable acidity and the concentration of added deoxidizers in a liquid medium and displays them on the indicator of the high-resistance converter, and also ensures that the sensor settings are stored in the memory according to the control solutions of the corresponding ion-selective sensor.

The disadvantage of analogue are limited functionality due to the use in the dairy industry.

A device for determining the pH of a liquid is also known (RF patent No. 2548131, G01N 27/30, G01N 27/333, G01N 27/74, published: 04/10/2015), containing a reference electrode, two ion-selective measuring electrodes and the first, second secondary measuring transducers , to the inputs of which the reference electrode and, accordingly, the first, second measuring electrodes are connected, and the outputs of the first and second secondary measuring transducers are connected to the inputs of the first and second voltage-to-digital converters, respectively, the outputs of which are connected to the microprocessor, the output of which is the output of the device, and the thermal parameters the inertia of the first and second measuring electrodes are equal, and the parameters of their isopotential points are different.

The disadvantage of analogue are limited functionality due to the use in hydrology.

Known pH sensor for a disposable container (RF patent No. 2752474, G01N 27/30, published: 07/28/2021), containing:

a plunger sleeve configured to be connected to the flange of the disposable container;

a plunger axially movable in the plunger sleeve between a storage position and an operating position;

a pH-sensitive element connected to the plunger, wherein the pH element is located in the storage chamber in the storage position and is made retractable inside the disposable container in the working position; and a temperature sensitive element located in the pH sensor and configured to sense temperature next to the pH sensitive element, which is a glass pH bulb connected to the glass tube, and the temperature sensitive element is located in the glass tube and is a thermocouple, further comprises a reference electrode connected to the plunger, wherein the reference electrode is configured such that at least a portion of the reference electrode extends inside the disposable container when the plunger is in the operating position, wherein the reference electrode includes at least one comparison transition, with in this case, the reference electrode is located in the reference electrolyte, and the reference electrode includes a silver wire coated with silver chloride, additionally contains a sealed electrical connector operatively connected to the pH-sensitive element and the temperature-sensitive element.

The disadvantage of analogue are limited functionality due to one-time use, as well as the unreliability of the design due to the presence of fragile glass elements.

The closest in technical essence and the achieved result to the claimed module is a system for determining the potential of the flow of a fluid medium (RF patent No. 2643683, G01F 1/64, published: 02/05/2018), containing: an electrode block containing a disk-shaped electrode and an annular electrode, separated from each other by an insulating gap, while the annular electrode surrounds the disk-shaped electrode along its outer perimeter; an actuating device configured to be connected to the electrode assembly to rotate the disc-shaped electrode and the annular electrode in the fluid under test,

wherein the disc-shaped electrode and the annular electrode are immersed in the fluid; and a measuring device for measuring electrical energy, configured to be electrically connected to the disc-shaped and annular electrodes of the electrode assembly and capable of measuring a potential difference between the disc-shaped and annular electrodes as the actuating device rotates the electrode assembly at a rotation speed to cause moving the fluid through the disc-shaped and ring-shaped electrodes, and the measured potential difference reflects the potential of the flow of the fluid.

The disadvantage of analogue are limited functionality and design complexity.

The objective of the utility model is to expand the functionality of the device by analyzing the ionic composition of the drilling mud and fluid.

The technical result is an increase in the accuracy of the electrochemical analysis of the ionic composition of the medium under study during hydrodynamic logging and testing of formations.

The problem is solved, and the technical result is achieved in that the multi-electrode module for analyzing the acidity of solutions contains a measuring chamber in which a measurement electrode, a reference electrode and a redox potential electrode are placed, a measuring device with a cover, made in the form of an electronic board with a microprocessor, in this case, the measuring chamber includes a sealing unit, a glass drop, a chamber with silicone oil, in which a channel for pouring silicone oil is made, a piston compensator and a glass flask located in the lower part of the measuring chamber.

The essence of the utility model is illustrated by drawings. In FIG. 1 shows a multi-electrode module for analyzing the acidity of solutions. In FIG. 2 (with remote elements) - measuring chamber and electrodes (arrows show the direction of flow of the investigated medium - solution).

The multielectrode module for analyzing the acidity of solutions contains a measuring chamber 1 (Fig. 1), in which three electrodes are placed: a measurement electrode (pH electrode) 2, a reference electrode 3 and an redox potential (ORP) electrode 4. The measuring device 5, made in the form of an electronic board with a microprocessor, located at a distance of 100 to 300 mm from the measuring chamber 1 with the measurement electrode 2, the reference electrode 3 and the ORP electrode 4. The cover 6 of the measuring device 5 ensures its sealing from the external environment and the investigated medium (solution). The measuring chamber 1 contains a sealing unit made of kovar 7 (Fig. 2), a glass drop 8, for example, from C-52 with soldered kovar wire, a chamber 9 with silicone oil, in which an oil filling channel 10 and a piston compensator 11 are made. flask 12, located in the lower part of the measuring chamber 1, is placed in the test medium 13.

Multielectrode module for analysis of the acidity of solutions works as follows. During hydrodynamic logging and testing of open hole formations, the studied medium (solution) with the help of a formation tester pump enters the measuring chamber 1, in which three electrodes are placed: measurement electrode (pH - electrode) 2, reference electrode 3 and redox potential electrode 4 The potential of the measuring electrode 2 and the redox electrode 4 depends on the composition of the investigated medium. Reference electrode 3 provides a reference potential. The potential difference between the pH electrode 2, the redox electrode 4 and the reference electrode 3 is recorded by the measuring device 5 (an electronic board with a microprocessor located at a distance of 100 to 300 mm from the measuring chamber 1 with a measurement electrode (pH electrode) 2, a reference electrode 3 and a redox potential electrode.The microprocessor of the measuring device 5 converts the potential difference according to the Nernst equation into the concentration of the determined ions of the medium under study, for example, drilling fluid or well fluid.Measuring chamber 1 with a measurement electrode (pH - electrode) 2, a reference electrode 3 and the redox electrode operates at high temperature (up to 90°C) and high pressure (up to 100 MPa), the measuring device 5 operates only at high ambient temperature - gas at a pressure of not more than 1 bar by sealing it from cover 6. Measuring chamber 1 ensures reliable operation of the measurement electrode (pH electrode) 2, reference electrode 3 and redox potential electrode in the medium under study 13 with high temperature and high pressure. Under the action of these factors, the measurement electrode (pH - electrode) 2, the reference electrode 3 and the redox potential electrode in the measuring chamber 1 can be destroyed, since the sensitive element of all electrodes is located inside the glass bulb 12. If the glass bulb 12 is not affected by only a compressive pressure force from all sides, but also an axial force in one direction, the glass bulb 12 will not withstand such a load and will collapse. It is necessary to exclude the effect of axial force on the glass bulb 12 of the measurement electrode (pH electrode) 2, the reference electrode 3 and the redox electrode.

Chamber 9 (with pre-installed measurement electrode (pH electrode) 2, reference electrode 3 and redox electrode) is filled with silicone oil using a syringe with a catheter to the level of channel cutoff 10. Then a piston compensator 11 is inserted into it, while displacing some oil. In this way chamber 9 will be filled without air bubbles. Under the action of high pressure of the investigated medium 13 (drilling mud or well fluid), the piston compensator 11 moves upward, compressing the silicone oil in the chamber 9, until the pressure of the silicone oil becomes equal to the pressure of the investigated medium 13. Thus, the glass bulb 12 of all electrodes perceives only the compressive force pressure from all sides, the action of any axial forces along the glass bulb 12 in this design is excluded.

It should be noted that the elements that are in the chamber 9 with silicone oil perceive both the pressure force and the axial force. Sealing unit 7 and glass drop with wire 8 are made of high-strength materials (seal unit 7 made of Kovar, glass drop 8 made of C-52) that can withstand high pressure up to 100 MPa and axial load up to several tons.

The combination of the claimed features (elements of the device) provides an increase in the accuracy of the electrochemical analysis of the ionic composition of the medium under study during hydrodynamic logging and testing of formations.

EXAMPLE OF A SPECIFIC IMPLEMENTATION OF A MULTIELECTRODE MODULE FOR ANALYSIS OF THE ACIDITY OF SOLUTIONS

An electronic board with a microprocessor is placed at a distance of 100 to 300 mm from the measuring chamber 1 with a measurement electrode (pH electrode) 2, a reference electrode 3 and a redox electrode. Measuring chamber 1 with measurement electrode (pH electrode) 2, reference electrode 3 and redox electrode operates at temperatures up to 90°C and pressures up to 100 MPa. Measuring device 5 operates only at high temperature in the environment - gas at a pressure of not more than 1 bar due to sealing it from the external environment and the investigated environment with a cover 6. The sealing unit 7 is made of kovar, and the glass drop 8 is made of C-52 alloy. These materials are able to withstand high pressure up to 100 MPa and axial load up to several tons. Drilling mud or borehole fluid is used as the test fluid.

As can be seen from the presented table, the claimed multielectrode module for analyzing the acidity of solutions in terms of its main parameters (indicators), such as temperature (up to 90 ° C) and pressure (up to 100 MPa), corresponds to and even surpasses the best foreign analogues (see the mentioned Internet resources - https://bazislab.ru/shop/oborudovanie-dlya-elektrohimicheskih-metodov-analiza/ph-metry/vlagozacshicshennyj-rn-s-f-metr-hi98127-phep-4 and https://www.izmteh.ru/promyshlennye /esp_01_14/).

So, the claimed utility model allows expanding the functionality of the device by analyzing the ionic composition of the drilling fluid and fluid, as well as improving the accuracy of the electrochemical analysis of the ionic composition of the drilling fluid and fluid during hydrodynamic logging and testing of formations.

Claims (1)

A multi-electrode module for analysis of the acidity of solutions, containing a measuring chamber in which a measuring electrode, a reference electrode and an electrode of redox potential are placed, a measuring device with a cover, made in the form of an electronic board with a microprocessor, while the measuring chamber includes a sealing unit, a glass drop, a chamber with silicone oil, in which there is a channel for pouring silicone oil, a piston compensator and a glass flask located in the lower part of the measuring chamber.

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