RU2751301C1 - Cell for study of phase equilibrium in gas-liquid system (variants) - Google Patents

Abstract

FIELD: oil industry.

SUBSTANCE: invention relates to the study of properties that characterize the thermodynamic phase equilibrium in gas-liquid systems, including at high pressures and temperatures, and in a supercritical fluid state, and can be used in the oil and gas industry to study the physical properties of reservoir fluids (oil - associated gas) in the wellhead and pipelines. According to the first variant, the cell for studying the phase equilibrium in the gas-liquid system contains a horizontally arranged cylindrical high-pressure chamber with grooves for sealing and threaded ends at each end. The sealing grooves are provided with sealing rings, for example, made of soft metal, elastomer, rubber, to which two fixed optical windows made of sapphire, quartz or other transparent material are installed using threaded bushings screwed into the threaded ends. In the wall of the cell chamber between the optical windows, there are radial threaded holes with temperature and pressure sensors installed in them and valves for the input and output of the medium. The cell chamber between two fixed optical windows contains a movable optical window enclosed in a sleeve and installed in the housing through an internal O-ring and pressed to the housing through a threaded connection by a lid equipped with an external O-ring. A movable optical window divides the volume of the cell into a chamber for the medium under study and a chamber for hydraulic fluid. Moreover, radially arranged through holes with threads in the wall of the cell chamber, with temperature and pressure sensors installed in them and valves for the input and output of media, have both a chamber for the medium under study and a chamber for hydraulic fluid, and are as close as possible to fixed optical windows. The medium inlet valve in the chamber for the test medium is connected to the container with the test medium. The medium outlet valve in the hydraulic fluid chamber is connected to the hydraulic fluid collection tank. The cell for studying the phase equilibrium in the gas-liquid system, according to the second variant, contains a hinge inside the chamber for hydraulic fluid, a cylindrical spring is installed coaxially with the axis of which, and one of the free ends of the hinge is inserted into a vertical groove in the body of the movable optical window, the other free end of the hinge is installed at the base of the fixed optical window. In this case, the medium inlet valve in the chamber for the medium under study is connected to the tank with the medium under study, and the medium outlet valve in the chamber for hydraulic fluid is connected to the atmosphere.

EFFECT: invention makes it possible to increase the information content and reduce the uncertainty of measurements of properties that characterize the thermodynamic phase equilibrium in gas-liquid systems, including at high pressures and temperatures in a supercritical fluid state.

2 cl, 3 dwg, 6 tbl, 2 ex

Description

The invention relates to the study of properties characterizing thermodynamic phase equilibrium in gas-liquid systems (hereinafter referred to as the investigated medium), including at high pressures and temperatures, and in a supercritical fluid state.

We are talking about such thermodynamic properties as PvT dependence, specific volume, solubility, critical parameters of the system (P _k , T _k , ν _k ), where P is the pressure, ν is the specific volume, T is the temperature, P _k is the critical pressure, ν _к - critical specific volume, Т _к - critical temperature. The invention can be used in the oil and gas industry to study the physical properties of formation fluids (oil - associated gas) at the wellhead and pipelines.

Known cell for studying the phase equilibrium of the gas-liquid system, including a vertically located cylindrical high-pressure chamber with a lower and upper cover, equipped with a stuffing box and valves, installed in a thermostatic casing with a distribution unit and a pressure gauge. A separating piston with a hydraulic drive is located in the cylindrical chamber, in which there is a meter in the form of a scale with a dial, fixed on the rod, and a mechanical drive made in the form of a screw with a nut to move the rod. In the housing of the separating piston there is an agitator made in the form of a rod passing through the stuffing box assembly, a folding spring connected to the separating piston, a drive made with cooling the stuffing box assembly in the form of a water jacket and connected to the electric motor rod with a variable speed. Pressure and temperature sensors are installed on the top cover of the cylindrical chamber and are connected through appropriate shut-off valves to the computer, see RU Patent No. 2201503, IPC Е21В 49/00 (2000.01), 2003.

The known cell allows you to determine the dependence P-V-T, but it does not allow you to determine the specific volume (v) and critical parameters of the system under study (P _k , T _k , ν _k ), where V is the volume. The stuffing box assemblies available in the cell require constant monitoring and maintenance and do not allow ensuring the tightness of the cylindrical chamber, which limits the use of the device at pressures up to 10 MPa. The leakage of the chamber leads to a violation of the thermodynamic equilibrium of the system under study, and, consequently, increases the measurement uncertainty of the PVT dependence.

Known cell for studying the phase equilibrium of the gas-liquid system, including a vertically located cylindrical high pressure chamber with a bottom and top cover. A sensing unit is installed inside the chamber, consisting of two spaced-apart connectors, a string suspended with tension between the connectors, and a magnet that creates a magnetic field interacting with the string. The string interacts with the environment under study. The rate of damping of the vibrations of the string is judged on the viscosity and the specific volume of the investigated medium, see RU Patent No. 2383734, IPC Е21В 49/10 (2006.01), G01N 11/16 (2006.01), 2010.

The well-known cell for research and phase equilibrium of the gas-liquid system does not allow determining the solubility and critical parameters of the system: P _to , T _to , ν _to .

Known cell for studying the phase equilibrium of the gas-liquid system, which contains a high-pressure flow chamber. Depending on the measured property of the investigated medium, the flow chamber can be equipped with various sensors or equipment. In one embodiment, a syringe pump integrated into the flow chamber is provided to measure the pressure and volume of an isolated test medium. In a second embodiment, a spectral detector optically coupled to the flow chamber can measure the hydrocarbon composition. In the third version, the specific volume and viscosity sensor can measure the specific volume and viscosity of the investigated medium. In the fourth version, temperature and pressure sensors can measure the temperature and pressure of the investigated medium. In the next version, the compressibility of the investigated medium can be measured using the pressure and volume control unit. In another embodiment, the pressure of the test medium can be reduced to a certain pressure such that, for example, asphaltenes precipitate. A further decrease in pressure can lead to the fact that the gas components will be separated from the liquid phase, for example, an ultrasonic sensor or an optical detector can be used to detect the emission of gas bubbles, see RU Patent No. 2392430, IPC Е21В 49/08 (2006.01), G01N 7 / 00 (2006.01), 2010

The known cell in each configuration of the flow chamber makes it possible to measure only one or two properties. Measurement of the properties of the investigated medium in the flow does not ensure the creation of the conditions for the thermodynamic equilibrium of the phases, which leads to the appearance of additional uncertainty in the values of these properties. The disadvantages of a flow-through cell can also be attributed to the large area occupied by the equipment and the large volume of the sample of the investigated medium.

Known cell for studying the phase equilibrium of the gas-liquid system, which is made in the form of a modular sensor unit, including a vertically located cylindrical high pressure chamber with grooves for sealing and threaded end connections at each end, so that they include protective plugs. The ends of the cylindrical chamber are closed with threaded protective plugs. The protective plugs are sealed on the cylindrical chamber with elastomeric O-rings installed in the grooves. Protective plugs are also used to seal the elongated portions of the chamber, which are located within the respective ends of the chamber for interaction with the pressure and temperature transducer, agitator mechanism, and ultrasonic transducer. The pressure and temperature sensors are integrated with the upper piston and the ultrasonic transducer is integrated with the lower piston. The chamber is divided into upper and lower parts, which are communicated through a narrow channel. The inner surfaces of the upper and lower parts of the chamber have a minimum roughness, which allows the sealing elements to provide the required tightness of both movable and fixed joints. In the region of the narrow channel, a hole is located perpendicular to its axis, passing through the channel walls and communicating with the channel. The hole diameter is equal to the diameter of the narrow channel and amounts to several millimeters. Fixed optical windows are installed at both ends of the hole. The windows are sealed to the chamber walls with elastomeric O-rings. The windows are pressed against the chamber wall with threaded bushings. The configuration of the seal created by the seal grooves further divides the top and bottom of the chamber into two more parts, forming a hydraulic side at the top and bottom of the chamber. A sample of the investigated medium is placed in all parts of the chamber, including the hydraulic side. The sample volume between the upper piston and the lower piston can be changed by moving the upper piston, see RU Patent No. 2606256, IPC G01N 11/16 (2006.01), Е21В 49/00 (2006.01), 2017

The disadvantages of the cell for studying the phase equilibrium in the gas-liquid system are the complexity of the design and the complexity of the measurement. The presence of two pistons dividing the cavity into four parts is difficult to manipulate to accurately bring the interface into the field of view of the optical windows. The presence of stuffing box assemblies of movable joints limits the use of the device at high pressures.

Known cell for the study of phase equilibrium in the gas-liquid system, consisting of a horizontally located cylindrical high-pressure chamber, in one end of which there are threaded holes for the bolts of the flange, and in the other end there is an internal thread for a differential screw. A sleeve is installed in the chamber, tightly fitting to the inner wall of the chamber. A stationary optical window is installed inside the sleeve, held in the sleeve by a fixed nipple, which is held by a flange bolted to the end of the camera through an O-ring and a metal ring, and a movable optical window held in the sleeve by a movable nipple, which, together with the window, is capable of movement using a differential screw screwed into the internal thread of the chamber, and the differential screw is connected by an internal thread to the movable nipple. In this case, the pitch of the external thread of the differential screw differs from the pitch of the internal thread by 0.2 mm. For a complete revolution of the differential screw, the movable window moves by 0.2 mm, changing the distance to the fixed window, thereby changing the volume of the investigated medium placed in the cell. And in the chamber wall in the area between the optical windows, the cell has radial threaded holes for installing temperature and pressure sensors, and for entering and leaving the investigated medium, see the journal "Supercritical fluids - theory and practice" vol. 2, No. 1, 2007, p. ... 47-48, Fig. 7.

Another design for moving the movable optical window is based on the use of a system of levers and a lead screw. The lead screw moves the slider associated with the first lever. In turn, it acts on a second lever connected to two rods with a camera. The whole system makes it possible to move the chamber with a short nipple fixed in it with a movable window relative to a fixed long nipple fixed at the base of the cell. The movement mechanism allows you to change the distance between the windows from 0 to 1.5 mm, see the journal "Supercritical fluids - theory and practice" vol. 2, no. 1, 2007, p. 47-48, Fig. five.

The disadvantages of the described cells for studying the phase equilibrium in the gas-liquid system include the absence of seals between the optical windows and the movable and fixed nipples. This can cause the test medium to flow from the high-pressure region into the environment and upset the thermodynamic phase equilibrium of the test medium, which creates a limitation in the use of the cell for low-molecular compounds, for example, hydrocarbons with less than eight carbon atoms. It is practically impossible to measure the absolute value of the distance between the movable and fixed optical windows, and, consequently, the absolute value of the volume of the investigated medium, due to thermal and mechanical deformations of the cell parts at high temperatures and pressures. As a result, the cell does not allow measuring the values of the specific volume, including its critical value, as well as the P-ν-T dependence of the medium under study.

The closest in technical essence is a cell for studying phase equilibrium in a gas-liquid system, containing a horizontally located cylindrical high-pressure chamber with grooves for sealing and threaded ends at each end, grooves for sealing are equipped with sealing rings, for example, made of soft metal, elastomer, rubbers, to which, using threaded bushings screwed into the threaded ends of the chamber, fixed optical windows made of sapphire, quartz or other transparent material are installed, and in the wall of the cell chamber between the optical windows there are radial threaded holes with temperature sensors installed in them and pressure, and valves for inlet and outlet of the investigated medium, see the journal "Supercritical fluids - theory and practice" vol. 2, no. 3, 2007, p. 81-97

The disadvantages of this cell for studying phase equilibrium in a gas-liquid system are low information content and high research uncertainty and the need to use external measuring devices. For example, to determine the P-ν-T dependence and solubility, it is necessary to take a sample for analysis, which violates the thermodynamic phase equilibrium of the medium under study. The cell does not allow measuring the value of the specific volume of the investigated medium, including its critical value. The uncertainty in measuring solubility by this method is estimated at 8-20%.

A technical problem is low information content and high uncertainty in measurements of properties characterizing thermodynamic phase equilibrium in the gas-liquid system, including at high pressure and temperature and in a supercritical fluid state.

The technical problem is solved by the fact that the cell for studying the phase equilibrium in the gas-liquid system according to the first option, containing a horizontally located cylindrical high-pressure chamber with grooves for sealing and threaded ends at each end, the grooves for sealing are equipped with sealing rings, for example, made of soft metal , elastomer, rubber, to which, using threaded bushings screwed into the threaded ends, two fixed optical windows made of sapphire, quartz or other transparent material are installed, and in the cell chamber wall between the optical windows there are radial threaded holes with installed in them with temperature and pressure sensors and valves for inlet and outlet of the medium, according to the invention, the cell chamber between two fixed optical windows contains a movable optical window enclosed in a sleeve and installed in the housing through an internal sealing ring, and pressed to the housing through a threaded connection by a cover, equipped with an external sealing ring, while the movable window divides the cell volume into a chamber for the investigated medium and a chamber for a hydraulic fluid, and radially located through holes with threads in the wall of the cell chamber, with temperature and pressure sensors installed in them and valves for inlet and outlet of the medium, has both a chamber for the investigated medium and a chamber for hydraulic fluid and is as close as possible to the fixed optical windows, while the medium inlet valve in the chamber for the investigated medium is connected to the container with the investigated medium, and the medium outlet valve in the chamber for the hydraulic fluid is connected to the container for collecting hydraulic fluid.

The technical problem is solved by the fact that the cell for studying the phase equilibrium in the gas-liquid system according to the second option, containing a horizontally located cylindrical high-pressure chamber with grooves for sealing and threaded ends at each end, the grooves for sealing are equipped with sealing rings, for example, made of soft metal , elastomer, rubber, to which, using threaded bushings screwed into the threaded ends, two fixed optical windows made of sapphire, quartz or other transparent material are installed, and in the cell chamber wall between the optical windows there are radial threaded holes with installed in them with temperature and pressure sensors and valves for inlet and outlet of the medium, according to the invention, the cell chamber between two fixed optical windows contains a movable optical window enclosed in a sleeve and installed in the housing through an internal sealing ring, and pressed to the housing through a threaded connection by a cover, equipped with an external sealing ring, while the movable optical window divides the cell volume into a chamber for the medium under study and a chamber for a hydraulic fluid, a hinge is installed inside the chamber for a hydraulic fluid, a coil spring is installed coaxially with the axis of which a cylindrical spring is installed, and one of the free ends of the hinge is inserted into a vertical groove in the housing of the movable optical window, the other free end of the hinge is installed at the base of the fixed optical window, and radially located through holes with threads in the wall of the cell chamber with temperature and pressure sensors installed in them, and valves for inlet and outlet of the medium has as a chamber for the medium under study, and the chamber for the hydraulic fluid and are as close as possible to the fixed optical windows, while the valve for the medium inlet in the chamber for the investigated medium is connected to the container with the investigated medium, and the valve for the outlet of the medium in the chamber for the hydraulic fluid is connected to the atmosphere.

The solution of the technical problem makes it possible to increase the information content and reduce the uncertainty of measurements of properties characterizing the thermodynamic phase equilibrium in gas - liquid systems, including at high pressures and temperatures in a supercritical fluid state. The uncertainty in the measurement of solubility is reduced by 1.5-2 times.

Cell design for studying phase equilibrium in the gas-liquid system according to the first option, see Fig. 1, contains a horizontally located cylindrical high-pressure chamber 1 with grooves for sealing 2 and threaded ends at each end, the grooves for sealing are equipped with sealing rings 3, for example, made of soft metal, elastomer, rubber, to which using threaded bushings 4 screwed into threaded ends of the cylindrical chamber 1, two fixed optical windows 5 are installed, made of sapphire, quartz or other transparent material, and in the wall of the cell chamber between the optical windows 5 there are radial threaded holes 6 with temperature sensors 7 and pressure 8 installed in them, and valves for inlet 9 and outlet 10 of the medium, according to the invention, the chamber 1 of the cell between two fixed optical windows 5 contains a movable optical window 11, enclosed in a sleeve 12 and installed in the housing 13 through an inner sealing ring 14, and pressed against the housing 13 through a threaded connection by a cover 15, equipped with an external sealing ring 16, while p A movable optical window 11 divides the volume of the cell into a chamber for the investigated medium 17 and a chamber for a hydraulic fluid 18, with radially threaded through holes in the wall of the chamber 1 of the cell 6 with temperature sensors 7 and pressure 8 installed in them, and input and output valves 9 10 of the medium has both a chamber for the investigated medium 17 and a chamber for the hydraulic fluid 18 and is as close as possible to the fixed optical windows 5, while the medium inlet valve 9 in the chamber for the investigated medium 17 is connected to the container 19 with the investigated medium, and the medium outlet valve 10 in the chamber for hydraulic fluid 18 is connected to a tank 20 for collecting hydraulic fluid, and the medium outlet valve 10 in the chamber for the test medium 17 is connected to a flask of variable volume 21 installed in a thermostat 22 with an overflow device and a volumetric flask 23.

Cell design for studying phase equilibrium in the gas-liquid system according to the second option, see Fig. 2, contains a horizontally located cylindrical high-pressure chamber 1 with grooves for sealing 2 and threaded ends at each end, the grooves for sealing are equipped with sealing rings 3, for example, made of soft metal, elastomer, rubber, to which by means of threaded bushings 4 screwed into threaded ends of the cylindrical chamber 1, two fixed optical windows 5 are installed, made of sapphire, quartz or other transparent material, and in the wall of the cell chamber between the optical windows 5 there are radial threaded holes 6 with temperature sensors 7 and pressure 8 installed in them, and valves for inlet 9 and outlet 10 of the medium, according to the invention, the chamber 1 of the cell between two fixed optical windows 5 contains a movable optical window 11, enclosed in a sleeve 12 and installed in the housing 13 through an inner sealing ring 14, and pressed against the housing 13 through a threaded connection by a cover 15, equipped with an external sealing ring 16, while p A movable optical window 11 divides the volume of the cell into a chamber for the investigated medium 17 and a chamber for a hydraulic fluid 18, with radially threaded through holes in the wall of the chamber 1 of the cell 6 with temperature sensors 7 and pressure 8 installed in them, and input and output valves 9 10 of the medium has both a chamber for the investigated medium 17 and a chamber for a hydraulic fluid 18 and is as close as possible to the fixed optical windows 5. A hinge 24-27 is installed inside the chamber for a hydraulic fluid 18, coaxially with the axis 26 of which a cylindrical spring 27 is installed, and one from the free ends of the hinge 24 is inserted into a vertical groove 28 in the housing 13 of the movable window 11, the other free end of the hinge 25 is installed at the base of the fixed window 5, and radially disposed through holes 6 are threaded in the wall of the cell chamber 1 with temperature sensors 7 and pressure 8, and valves inlet 9 and outlet 10 of the medium has 17 as a chamber for the investigated medium, t as well as the chamber for the hydraulic fluid 18 and are as close as possible to the fixed optical windows 5, while the medium inlet valve 9 in the chamber for the investigated medium 17 is connected to the container with the investigated medium 19, and the outlet valve of the medium 10 in the chamber for the hydraulic fluid 18 is connected to the atmosphere , and the valve for the outlet of the medium 10 in the chamber for the investigated medium 17 is connected to a flask of variable volume 21 installed in a thermostat 22 with an overflow device and a volumetric flask 23.

The inner surface of the high-pressure chamber has a geometry and a minimum roughness, allowing the O-rings to provide the required tightness of both movable and fixed joints. The movement of the movable optical window between the fixed windows is due to a small pressure drop between the chambers. An inner O-ring installed between the sleeve and the body seals both the joint between the sleeve and the body and the gap between the sleeve and the body with a movable optical window. An outer sealing ring installed between the body and the cover seals both the joint between the body and the cover and the gap between the inner surface of the camera and the body of the movable optical window. The volume of the investigated medium or its change in the chamber for the investigated medium according to the first variant is determined by the volume of the displaced or introduced hydraulic fluid from (or into) the chamber (y) for the hydraulic fluid. The hydraulic fluid must be slightly compressible and optically clear, such as water. The exact value of the volume of hydraulic fluid is determined by correcting for compressibility. The sensors used for measuring temperature 7 (Fig. 1, Fig. 2) and pressure 8, as well as the valves inlet 9 and outlet 10 of the medium do not have a dead volume. The installation of these sensors and valves in radially located through holes 6 with threads in the wall of the chamber 1 is made so that they are flush with the inner surface of the cylindrical chamber and do not form an additional dead volume of the investigated medium and hydraulic fluid. When measuring solubility, in order to exclude disturbance of the thermodynamic phase equilibrium of the test medium during sampling from the chamber for the test medium, a hydraulic fluid is introduced into the chamber for hydraulic fluid 18 so that the pressure of the experiment does not change during sampling.

The second option for determining the volume is based on measuring the distance between the fixed and movable hinge windows installed in the chamber for the medium under study. The free ends of the hinge are moved apart by means of a cylindrical spring installed coaxially with the axis of the hinge and touch the movable and fixed optical windows. To ensure the opening of the rods in the vertical plane, it is necessary that one of the ends of the rod, touching the movable window on the side of the chamber with hydraulic fluid, should enter the vertical groove in the cover. The distance between the windows is calculated from the amount of lift of the end of the hinge with the axis relative to the ends touching the windows. The amount of lift of the end of the hinge with the axis is remotely measured with a cathetometer through the optical windows. The opening angle of the hinge should be approximately in the range of 20 ° ÷ 160 °, which provides an uncertainty in measuring the distance between the windows of no more than ± 0.05 mm. The main parts of the hinge, in addition to the spring, are made of the same material as the high-pressure chamber, which makes it possible to take into account both the thermal elongation and the elongation of the chamber from the action of pressure when determining the volume of the investigated medium. Air or other inert gas with better optical characteristics than liquids can be used as a hydraulic fluid. To exclude a violation of the thermodynamic phase equilibrium of the test medium during sampling, a hydraulic fluid is introduced into the chamber for hydraulic fluid 18 so that the pressure of the experiment does not change during sampling.

The pressure in the experiments for both the first and the second versions of the cell for the study of phase equilibrium is determined by the pressure sensor 8 (Fig. 1, Fig. 2) SAPPHIRE pre-calibrated according to the model MP-600 deadweight manometer of accuracy class 0.01. The temperature in experiments for both versions is determined by the chromel-alumel thermocouple 7 (Fig. 1, fig. 2), previously calibrated against the standard platinum resistance thermometer PTS-10 of the first category with an uncertainty of ± 0.002 K. Cold junctions of the chromel-alumel thermocouple are placed in a thermostat with melting ice from distilled water. To determine the specific volume of the investigated medium in experiments for both versions, it is necessary to measure the mass of the investigated medium and hydraulic fluid. To measure the mass of the investigated medium and hydraulic fluid, use a special VLE-2503S1 class 1 analytical balance with the largest measured mass of 2500 g and an uncertainty of 0.001 g.

Below are examples of determining the P-ν-T dependence of propane for the declared object.

Example 1

Determination of the P-ν-T dependence of propane at a temperature of 317.42K using a cell for studying phase equilibrium according to the first embodiment, see FIG. 1. To do this, carry out the following sequential operations:

1. Set in the cell for the study of phase equilibrium room temperature T ₀ .

2. Open the medium outlet valves 10 in the chambers for the test medium 17 and for the hydraulic fluid 18. In this case, the chamber for the test medium is connected to a vacuum pump, and the chamber for the hydraulic fluid is connected to the environment at a pressure P ₀ .

3. The chamber for the test medium is evacuated. Under the action of the resulting pressure drop between the chambers, the movable optical window 11, assembled with the sleeve 12, the body 13, the cover 15 and the O-rings 14 and 16 (hereinafter the movable optical window assembly) comes into contact with the fixed optical window 5 in the chamber for the investigated environment 17. As a result of this action, the volume of the chamber for the investigated environment becomes equal to zero.

4. The hydraulic fluid chamber is evacuated through the open medium outlet valve 10 in the hydraulic fluid chamber 18.

5. Close the medium outlet valves 10 in the chambers for the test medium 17 and for the hydraulic fluid 18.

6. Open the valve to enter the medium 9 in the chamber for hydraulic fluid 18. Through valve 9, hydraulic fluid is introduced into the chamber for hydraulic fluid 18. In our experiments, distilled and deaerated water was used as the hydraulic fluid.

7. Close the medium injection valve 9 in the hydraulic fluid chamber 18.

8. Set the temperature of the experiment in the cell for the study of phase equilibrium. For our example, the temperature of the experiment is T ₁ = 317.42 K, which is measured by a chromel-alumel thermocouple 7.

с помощью аналитических весов. В наших экспериментах в качестве исследуемой среды использовался пропан.9. Determine the mass of the container 19 with the test medium

using an analytical balance. In our experiments, propane was used as the test medium.

10. Open the valve for introducing the medium 9 into the chamber for the test medium 17. Through the valve 9, the test medium is introduced from the container 19 with the test medium into the chamber for the test medium 17.

11. Set in the chamber for the investigated medium 17 cells for the study of phase equilibrium, the pressure of the experiment. For our example, the experimental pressure is P ₁ = 2.0 MPa.

12. Determine the mass m _{T0 of the} reservoir 20 for collecting hydraulic fluid using an analytical balance.

13. Open the medium outlet valve 10 in the hydraulic fluid chamber 18. Preliminarily, I connect the valve 10 in the hydraulic fluid chamber to a reservoir for collecting the hydraulic fluid. Under the action of the resulting pressure difference between the chambers, the movable optical window 11 in the assembly begins to move towards the fixed optical window 5 in the chamber for hydraulic fluid 18. The valve opening degree is adjusted so that the moving window speed does not exceed 1 mm per minute. In this case, part of the hydraulic fluid will be displaced and collected in a reservoir for collecting hydraulic fluid. When the movable optical window 11 assembly takes approximately the middle position between the fixed optical windows 5, the medium outlet valve 10 in the hydraulic fluid chamber 18 is closed.

14. Close the valve for introducing the medium 9 in the chamber for the test medium 17.

15. Determine the mass m _{T1 of the} reservoir for collecting hydraulic fluid with the displaced hydraulic fluid using an analytical balance.

16. Determine the mass of the displaced hydraulic fluid (in our case, water) according to the dependence: m _в1 = m _T1 -m _T0 .

Объем исследуемой среды пропана, находящейся в камере для исследуемой среды, равен объему вытесненной воды из камеры для гидравлической жидкости.17. Determine the volume of displaced water V _in1 . To do this, using reference tables, for example, the Handbook on the thermophysical properties of gases and liquids (Vargaftik N.B. Nauka, Moscow, 1972, 720 p.), We determine the specific volume of water ν _в1 and the coefficient of compressibility of water β _в1 at the temperature and pressure of the experiment. Calculate the volume of displaced water according to the dependence:

The volume of the propane test medium in the test medium chamber is equal to the volume of water displaced from the hydraulic fluid chamber.

с помощью аналитических весов.18. Determine the mass of the container with the propane remaining after the experiment.

using an analytical balance.

19. Calculate the mass of propane in the chamber for the investigated medium 17 according to the dependence:

20. Calculate the value of the specific volume of propane sought in the experiment at temperatures of 317.42K and a pressure of 2.0 MPa according to the dependence: ν _n1 = (V _b1 / m _n1 ). As a result, we obtain ν _n1 = 0.00216 m ³ / kg. At these values of temperature and pressure, propane is in a liquid state, which can be seen through the optical windows, see Fig. 3.

21. Open the medium outlet valve 10 in the hydraulic fluid chamber 18. The valve opening degree is adjusted so that the moving window speed does not exceed 1 mm per minute. The water displaced from the hydraulic chamber is collected in the same reservoir for the hydraulic fluid and added to the water that was collected in item 13.

22. Through a fixed optical window 5, the state of propane is observed.

23. When the first gas bubble appears in the liquid propane, the medium outlet valve 10 in the hydraulic fluid chamber is closed.

24. Determine the pressure by the pressure sensor 8. The pressure sensor shows the value P ₂ = 1.520 MPa.

26. Determine the mass of displaced water according to the dependence: m _в2 = m _T2 -m _T0 .

25. Determine the mass t _{T2 of the} container for collecting hydraulic fluid with displaced water, which is the sum of the masses of water displaced in paragraphs 13 and p. 21-23 using an analytical balance.

Объем исследуемой среды -пропана, находящейся в камере для исследуемой среды, равен объему вытесненной воды из камеры для гидравлической жидкости.27. Determine the volume of displaced water V _B2 . To do this, using reference tables, for example, the Handbook on the thermophysical properties of gases and liquids (Vargaftik N.B. Nauka, Moscow, 1972, 720 p.), We determine the specific volume of water ν _в2 and the coefficient of compressibility of water β _в2 at the temperature and pressure of the experiment. Calculate the volume of displaced water according to the dependence:

The volume of the test medium - propane, which is in the chamber for the test medium, is equal to the volume of water displaced from the chamber for the hydraulic fluid.

28. Calculate the value of the specific volume of propane sought in the experiment at a temperature of 317.42K and a pressure of 1.520 MPa according to the dependence: ν _n2 = (V _b2 / m _n1 ). As a result, we obtain _c2 = 0.00217 ν m ³ / kg. At these temperatures and pressures, propane is in a saturated liquid state, see FIG. 3.

29. Open the medium outlet valve 10 in the hydraulic fluid chamber 18. The valve opening degree is adjusted so that the moving window speed does not exceed 1 mm per minute. The water displaced from the hydraulic chamber is collected in the same reservoir for the hydraulic fluid and added to the water that was collected in item 13 and in item 13. 21-23.

30. The state of propane is observed through a fixed optical window 5. The meniscus of the liquid gradually descends to the bottom of the chamber for the investigated medium 17.

31. As soon as the last drop of liquid propane disappears and the entire volume of the chamber for the test medium 17 is filled with gaseous propane, the medium outlet valve 10 in the chamber for the hydraulic fluid is closed.

32. Determine the pressure by the pressure sensor 8. The pressure sensor shows the value P ₃ = 1.520 MPa.

33. Determine the mass m _{T3 of the} tank for collecting hydraulic fluid with displaced water, which is the sum of the masses of water displaced in item 13, p. 21-23 and p.p. 29-31 using an analytical balance.

34. Determine the mass of displaced water according to the dependence: m _в3 = m _T3 -m _T0 .

Объем исследуемой среды -пропана, находящейся в камере для исследуемой среды, равен объему вытесненной воды из камеры для гидравлической жидкости.35. Determine the volume of displaced water V _в3 . To do this, using reference tables, for example, the Handbook on the thermophysical properties of gases and liquids (Vargaftik N.B. Nauka, Moscow, 1972, 720 p.), We determine the specific volume of water ν _в3 and the coefficient of compressibility of water β _в3 at the temperature and pressure of the experiment. Calculate the volume of displaced water according to the dependence:

The volume of the test medium - propane, which is in the chamber for the test medium, is equal to the volume of water displaced from the chamber for the hydraulic fluid.

36. The value of the specific volume of propane sought in the experiment is calculated at a temperature of 317.42K and a pressure of 1.520 MPa according to the dependence: ν _n3 = (V _in3 / m _n1 ). As a result, we obtain ν _n3 = 0.0295 m ³ / kg. At these temperatures and pressures, propane is in a saturated gaseous state, see FIG. 3.

37. The medium outlet valve 10 in the hydraulic fluid chamber 18 is opened. The valve opening degree is adjusted so that the speed of movement of the movable window does not exceed 1 mm per minute. The water displaced from the hydraulic chamber is collected in the same container for the hydraulic fluid and added to the water that was collected in item 13, in item 13. 21-23 and p.p. 29-31.

38. Upon reaching a lower pressure, for example, P ₄ = 1.0 MPa. Close the medium outlet valve 10 in the hydraulic fluid chamber.

39. Determine the mass m _{T4 of the} tank for collecting hydraulic fluid with displaced water, which is the sum of the masses of water displaced in item 13, p. 21-23, p.p. 29-31 and p.p. 37-38 using an analytical balance.

40. Determine the mass of displaced water according to the dependence: m _в4 = m _T4 -m _T0 .

Объем исследуемой среды - пропана, находящейся в камере для исследуемой среды, равен объему вытесненной воды из камеры для гидравлической жидкости.41. Determine the volume of displaced water V _v1 . To do this, using reference tables, for example, the Handbook on the thermophysical properties of gases and liquids (Vargaftik N.B. Nauka, Moscow, 1972, 720 p.), We determine the specific volume of water ν _в4 and the compressibility coefficient of water β _в4 at the temperature and pressure of the experiment. Calculate the volume of displaced water according to the dependence:

The volume of the test medium, propane, in the test medium chamber is equal to the volume of water displaced from the hydraulic fluid chamber.

42. Calculate the value of the specific volume of propane sought in the experiment at a temperature of 317.42K and a pressure of 1.0 MPa according to the dependence: ν _n4 = (V _b4 / m _n1 ). As a result, we obtain ν _n4 = 0.0508 m ³ / kg. At these temperatures and pressures, propane is in a gaseous state, see FIG. 3.

FIG. 3 and Tables 1 and 2 show the P-ν-T dependence for propane, measured by the cell for studying the phase equilibrium according to the first embodiment, where Table 2-ν 'and ν' 'are the specific volumes of the liquid and gas phases on the saturation line.

Example 2. Determination of the P-ν-T dependence of propane at a temperature of 317.42K using a cell for studying phase equilibrium according to the second embodiment, see FIG. 2. To do this, carry out the following sequential operations:

1. In Example 1, steps 1-9 are repeated. Air or other inert gas can be used as the hydraulic fluid. As a result of these operations, the distance between the movable 11 and the fixed 5 windows in the chamber for the investigated liquid 17 is equal to zero (L ₀ = 0 mm), respectively, and the volume of the investigated medium V _n0 = 0 m ³ .

где с - длина стороны равностороннего шарнира (расстояние от конца шарнира с осью до свободного конца).2. Measure with a cathetometer the height h _{0 of the} lift of the end of the hinge with the axis 20-23 relative to the free ends 20 and 21, touching the windows. Calculate the distance between the free ends of the hinge, touching the windows by dependence

where c is the length of the side of the equilateral hinge (the distance from the end of the hinge with the axis to the free end).

3. In Example 1, steps 10-11 are repeated.

4. Open the medium outlet valve 10 in the chamber for hydraulic fluid 18. Under the action of the resulting pressure difference between the chambers, the movable optical 11 assembly begins to move towards the fixed optical window 5 in the chamber for hydraulic fluid 18. The valve opening degree is adjusted so that the speed the movement of the movable window did not exceed 1 mm per minute, while part of the hydraulic fluid will be displaced into the environment from the hydraulic fluid chamber. When the movable optical window 11 assembly takes approximately the middle position between the fixed optical windows 5, the medium outlet valve 10 in the hydraulic fluid chamber 18 is closed. Together with the movable optical window 11, the free end of the hinge 20 will move, inserted into the vertical groove 24 in the housing 13 of the movable window 11. As a result, the lifting height of the end of the hinge with the axis 20-23 relative to the free ends 20 and 21 touching the windows will increase.

5. In Example 1, step 14 is repeated.

Величину L₁ вычисляют по зависимости:

6. Determine the distance between the movable and fixed optical windows in the chamber for the investigated medium L ₁ . To do this, measure with a cathetometer the height h _{1 of the} lift of the end of the hinge with the axis 20-23 relative to the free ends 20 and 21 touching the windows. Calculate the distance between the free ends of the hinge, touching the windows by dependence

The value of L _{1 is} calculated according to the dependence:

где D - диаметр внутренней поверхности цилиндрической камеры с учетом расширения от температуры и давления.7. Calculate the volume of the investigated medium according to the dependence:

where D is the diameter of the inner surface of the cylindrical chamber, taking into account the expansion from temperature and pressure.

8. In Example 1, steps 18 and 19 are repeated.

9. Calculate the value of the specific volume of propane sought in the experiment at a temperature of 317.42K and a pressure of 2.0 MPa according to the dependence: ν _n1 = (V _n1 / m _n1 ). As a result, we obtain ν _n1 = 0.00215 m ³ / kg. At these values of temperature and pressure, propane is in a liquid state, which can be seen through the optical windows, see Fig. 3.

10. Open the medium outlet valve 10 in the hydraulic fluid chamber 18. The valve opening degree is adjusted so that the moving window speed does not exceed 1 mm per minute. The hydraulic fluid displaced from the hydraulic chamber is discharged into the environment.

11. In Example 1, steps 22-24 are repeated.

Величину L₂ вычисляют по зависимости:

12. Determine the distance between the movable and fixed optical windows in the chamber for the investigated medium L ₂ . To do this, measure with a cathetometer the height h _{2 of the} lift of the end of the hinge with the axis 20-23 relative to the free ends 20 and 21 touching the windows. Calculate the distance between the free ends of the hinge, touching the windows by dependence

The value of L _{2 is} calculated according to the dependence:

13. Calculate the volume of the investigated medium according to the dependence:

14. The value of the specific volume of propane sought in the experiment is calculated at a temperature of 317.42 K and a pressure of 1.520 MPa according to the dependence: ν _n2 = (V _n2 / m _n1 ). As a result, we obtain ν _n2 = 0.00216 m ³ / kg. At these temperatures and pressures, propane is in a saturated liquid state, see FIG. 3.

15. Open the medium outlet valve 10 in the hydraulic fluid chamber 18. The valve opening degree is adjusted so that the moving window speed does not exceed 1 mm per minute. The hydraulic fluid displaced from the hydraulic chamber is discharged into the environment.

16. In Example 1, steps 30-32 are repeated.

Величину L₃ вычисляют по зависимости:

17. Determine the distance between the movable and fixed optical windows in the chamber for the investigated medium L ₃ . To do this, measure with a cathetometer the height h _{3 of the} lift of the end of the hinge with the axis 20-23 relative to the free ends 20 and 21 touching the windows. Calculate the distance between the free ends of the hinge, touching the windows by dependence

The value of L _{3 is} calculated according to the dependence:

18. Calculate the volume of the investigated medium according to the dependence:

19. Calculate the value of the specific volume of propane sought in the experiment at a temperature of 317.42K and a pressure of 1.520 MPa according to the dependence: ν _n3 = (V _n3 / m _n1 ). As a result, we obtain ν _n3 = 0.0296 m ³ / kg. At these temperatures and pressures, propane is in a saturated gaseous state, see FIG. 3.

20. Open the medium outlet valve 10 in the hydraulic fluid chamber 18. The valve opening degree is adjusted so that the moving window speed does not exceed 1 mm per minute. The hydraulic fluid displaced from the hydraulic chamber is discharged into the environment.

21. In Example 1, steps 38 are repeated.

Величину L₄ вычисляют по зависимости:

22. Determine the distance between the movable and fixed optical windows in the chamber for the investigated medium L ₄ . To do this, measure with a cathetometer the height h _{4 of the} lift of the end of the hinge with the axis 20-23 relative to the free ends 20 and 21 touching the windows. Calculate the distance between the free ends of the hinge, touching the windows by dependence

The L ₄ value is calculated according to the dependence:

23. Calculate the volume of the investigated medium according to the dependence:

24. Calculate the value of the specific volume of propane sought in the experiment at a temperature of 317.42K and a pressure of 1.0 MPa according to the dependence: ν _n4 = (V _n4 / m _n1 ). As a result, we obtain ν _n4 = 0.0509 m ³ / kg. At these temperatures and pressures, propane is in a gaseous state, see FIG. 3.

Tables 3 and 4 show the P-ν-T dependence for propane, measured by a cell for studying phase equilibrium according to the second embodiment, where in Table 4-ν 'and ν' 'are the specific volumes of the liquid and gas phases at the saturation line.

The uncertainty of the pressure measurement was within ± 0.001 MPa, and the uncertainty of the temperature measurement was within ± 0.01 K. The deviation of the measured values of the specific volume from the reference values did not exceed 0.5%, see. Vargaftik N.B. Handbook on the thermophysical properties of gases and liquids. Nauka, Moscow, 1972, 720 p.

Table 5 shows the measured values of the critical parameters of propane (P _to , T _to , ν _to ). The critical parameters of propane are determined by the onset of critical opalescence. To do this, repeat Example 1 and Example 2 at higher temperatures and pressures until the moment of critical opalescence is detected through the optical windows. FIG. 3 it looks like a complete darkening of the medium under study in the optical cell (photo with a black circle).

Table 5 shows that the discrepancy between the critical values measured in the cells according to the first and second versions and the reference values does not exceed: by pressure 0.001 MPa, by temperature - 0.02 K and by specific volume - 0.00002 m ³ / kg.

Table 6 shows the results of measuring the solubility (Y) of naphthalene in carbon dioxide at a pressure of 20.7 MPa using cells for research according to the first and second options. In the experiments, carbon dioxide was in a supercritical fluid state, and naphthalene was in a liquid state. Measurements of the solubility of the substance in the solvent in the chamber for the investigated medium 17 (Fig. 1, 2) at the given values of temperature and pressure and intensive stirring of the substance taken in excess until saturation, followed by settling to achieve equilibrium, and sampling through the open valve 10 in the chamber for the investigated medium 17, by throttling to atmospheric pressure in a flask of variable volume 21, determining the volume of gas in the sample by the volume of the displaced thermostatic liquid from a thermostat with an overflow device 22 into a volumetric flask 23, venting gas from a flask of variable volume 21 and determining mass of liquid M _Y in the sample by weighing a flask of variable volume on a balance, followed by subtracting the mass of an empty flask of variable volume. To exclude a violation of the thermodynamic phase equilibrium of the medium under study during sampling, a hydraulic fluid is introduced into the chamber for hydraulic fluid 18 so that the pressure of the experiment does not change during sampling. Determine the mass of the gas M _{X by} dividing it by the specific volume of the gas. Solubility is calculated by the formula

where Y is the solubility of the substance in the solvent

μ _Y is the molecular weight of the liquid,

μ _X is the molecular weight of the gas.

As can be seen from table 6, the discrepancy between the values of the solubility of naphthalene in carbon dioxide obtained using cells for research according to the first and second variants of the claims does not exceed 6.2%. And the discrepancy between the values of the solubility of naphthalene in carbon dioxide, obtained in this work with the literature data, does not exceed 8.3%. The uncertainty in the measurement of solubility is in the range of 6-10%.

Thus, on the basis of the studies carried out, the declared object, a cell for studying phase equilibrium in the gas-liquid system, makes it possible to increase the information content and reduce the uncertainty in the measurements of the properties. The claimed object allows you to determine the P-ν-T dependence, specific volume, solubility, critical parameters of the system (P _to , T _to , ν _to ). The uncertainty in the measurement of solubility is reduced by 1.5-2 times.

Claims (2)

1. A cell for studying phase equilibrium in a gas-liquid system, containing a horizontally located cylindrical high-pressure chamber with grooves for sealing and threaded ends at each end, the grooves for sealing are equipped with sealing rings, for example, made of soft metal, elastomer, rubber, to which with the help of threaded bushings screwed into the threaded ends, two fixed optical windows are installed, made of sapphire, quartz or other transparent material, and in the cell chamber wall between the optical windows there are radial threaded holes with installed temperature and pressure sensors and inlet valves and outlet of the medium, characterized in that the cell chamber between two fixed optical windows contains a movable optical window enclosed in a sleeve and installed in the housing through an inner sealing ring and pressed against the housing through a threaded connection by a cover provided with an external sealing ring, while moving The rear optical window divides the cell volume into a chamber for the investigated medium and a chamber for a hydraulic fluid, and radially located through holes with a thread in the wall of the cell chamber, with temperature and pressure sensors installed in them and valves for inlet and outlet of the medium, has as a chamber for the medium under investigation and the chamber for the hydraulic fluid, and are as close as possible to the fixed optical windows, while the valve for introducing the medium in the chamber for the investigated medium is connected to the container with the investigated medium, and the valve for leaving the medium in the chamber for the hydraulic fluid is connected to the container for collecting the hydraulic fluid. 2. A cell for studying the phase equilibrium in the gas-liquid system, containing a horizontally located cylindrical high-pressure chamber with grooves for sealing and threaded ends at each end, the grooves for sealing are equipped with sealing rings, for example, made of soft metal, elastomer, rubber, to which with the help of threaded bushings screwed into the threaded ends, two fixed optical windows are installed, made of sapphire, quartz or other transparent material, and in the cell chamber wall between the optical windows there are radial threaded holes with installed temperature and pressure sensors and inlet valves and outlet of the medium, characterized in that the cell chamber between two fixed optical windows contains a movable optical window enclosed in a sleeve and installed in the housing through an inner sealing ring and pressed against the housing through a threaded connection by a cover provided with an external sealing ring, while moving The rear optical window divides the cell volume into a chamber for the medium under study and a chamber for a hydraulic fluid; a hinge is installed inside the chamber for a hydraulic fluid; the free end of the hinge is installed at the base of the fixed optical window, and the radially disposed threaded through holes in the wall of the cell chamber, with temperature and pressure sensors and medium inlet and outlet valves installed in them, have both a chamber for the medium under study and a chamber for a hydraulic fluid and are as close as possible to the fixed optical windows, wherein the medium inlet valve in the chamber for the investigated medium is connected to the container with the investigated medium, and the medium outlet valve in the chamber for the hydraulic fluid is connected to the atmosphere.

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