RU2342528C1 - Device for measuring quantity of oil and oil gas - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: invention refers to oil extraction, particularly to devices for measuring quantity of oil and oil gas extracted from deposits and can be employed for records management of production yield of oil and gas condensate wells (separate as well as clusters) and licensed places in systems of pressure-sealed gathering. To obtain the said the device incorporates capacity, separation facility and pipelines supplying water-oil-gas mixture together with pipelines withdrawing oil gas and water-oil emulsion. The capacity is made in form of a column plugged at ends. The axis of the column is perpendicular or inclined to horizontal surface. The water-oil-gas supplying pipeline is connected to the separation facility which divides the column into upper and lower portions connected or not connected to each other. The water-oil emulsion withdrawal pipeline is connected to the lower portion of the column. The oil gas withdrawal pipeline is connected to the upper portion of the column. The oil gas withdrawal pipeline is equipped with a device for measuring quantity of oil gas. One or more sensors are installed in the column. Also diameters of upper and lower portions are made equal or not equal and lengths of portions are made equal or not equal.

EFFECT: upgraded accuracy of measurements and reduced time for their execution, also upgraded reliability of operation and simplification of usage.

17 cl, 2 dwg

Description

The claimed invention relates to oil production, and in particular to devices for measuring the amount of oil and gas extracted from the subsoil, and can be used for operational accounting of production rates of oil and gas condensate wells (both individual and well) and license areas in pressurized collection systems .

A device for measuring the amount of oil and oil gas containing a measuring tank, a gas pipeline and pipelines for supplying and discharging an oil and gas mixture, in which there is a device for determining the time of filling a measuring tank of a fixed volume of oil-water emulsion partially separated from oil gas with a gas pipeline open to the collector and closed the outlet pipe of the water-oil mixture, a device for measuring excess pressure, temperature, displacement rate capacity after closing the gas pipeline and opening the pipe branch of the oil-gas mixture / Certificate for Utility Model No. 22179, IPC ⁷ ЕВВ 47/10, published 2002. Bulletin No. 7 /.

The disadvantages of the known device are:

- low accuracy and instability of measurements with increased foaming and high flow rates of wells, as well as with a large amount of dissolved oil gas;

- significant measurement time due to the need to displace the contents of the container after closing the gas pipeline;

- the complexity of operation in the winter, as there is a high likelihood of freezing of cranes with a high water content of oil-water emulsion or idle wells.

A device for measuring the amount of oil and oil gas containing a measuring tank, a gas pipeline and pipelines for supplying and discharging a water-oil and gas mixture, in which the filling of a measuring tank of a calibrated volume is performed with a gas pipeline open to a collector and a closed pipeline for discharging a water-oil-gas mixture, a hydrostatic pressure measuring sensor at the known height of the liquid column, overpressure, temperature, rate of displacement of the contents of the container after closing the gas pipeline and opening the branch pipe for the diversion of well products to the reservoir, the filling time of the measuring tank, and also a device for measuring the height of the liquid column and hydrostatic pressure / RF Patent No. 2220282, IPC ⁷ ЕВВ 47/10, published on December 27, 2003. Bulletin No. 36 /.

The disadvantages of the known device are:

- low accuracy and instability of measurements, due to the need to withstand the production of the well contained in the measuring tank to a state of complete absence of bubble gas and foam settling, which greatly complicates the measurement, especially with medium and high foam oils, as well as the complexity of measurements at high pressure oil-gas mixture ;

- significant measurement time due to the need for such exposure;

- the complexity of operation in the winter, as there is a high probability of freezing of cranes at high water cuts or idle wells;

- the complexity of management due to the need to open and close the gas pipeline and pipe branch of the production of wells to the reservoir.

A device is known for measuring the amount of oil and oil gas, comprising a column plugged from above and made of a pipe with pipelines for supplying a water-oil mixture and for removing a water-oil emulsion and oil gas, in which the column is located in the well, the bottom of the column is open, the axis of the column coincides with the axis of the well , the pipeline for supplying the oil and gas mixture is connected to the upper part of the column tangentially / RF Patent No. 2252312, IPC ⁷ ЕВВ 43/38, published on 05/20/2005. Bulletin No. 14 /.

The disadvantages of the known device are:

- insufficient measurement accuracy, since the separation of the oil-gas mixture into a water-oil emulsion and oil gas requires complex adjustment depending on the flow of the oil-gas mixture, gas factor, etc., therefore, when changing the operating mode and / or changing the production mode, the measurement accuracy deteriorates ;

- a large duration of measurements, since for their implementation it is necessary to completely fill the well with a water-oil emulsion; with a long duration, the destruction of the oil-water emulsion into oil and water occurs, so the density of the oil-water emulsion becomes uneven;

- lack of reliability, since a complex setting is required for each well or wellbore, which can easily be violated, for example, when changing the production mode, the number of producing wells, etc .;

- complexity of use, since it can only be used in a well equipped with a packer.

The closest in technical essence and the achieved result is a device for measuring the amount of oil and oil gas containing a container, a separation device and pipelines for supplying a water-oil mixture, a discharge of oil gas and a water-oil emulsion, which contains a calibrated measuring tank for a water-oil emulsion located perpendicular to the horizontal surface and equipped with level sensors (filling), hydrostatic and gauge pressure, thermometer and timer, as well as with a flow switch, the separation device is made in the form of a volumetric gas separator, the gas lines of the volumetric gas separator and the calibrated measuring capacitance are connected using a flow switch, and the level sensor of the calibrated measuring capacitance is made analog with the ability to monitor any liquid level / cm. RU 2220282 C1, cl. ЕВВ 47/10, 12/27/2003, 7 pp. /.

The disadvantages of the known device for measuring the amount of oil and gas are:

- low accuracy and instability of measurements, due to the need to withstand the production of the well contained in the calibrated measuring tank to a state of complete absence of bubble gas and foam settling, which greatly complicates the measurement, especially with medium and high foam oils, as well as the complexity of measurements at high pressure oil-gas mixtures;

- significant measurement time due to the need for such exposure;

- the complexity of operation in the winter, as there is a high probability of freezing of cranes in case of high water cut and / or idle wells;

- control complexity due to the need to open and close the flow switch connecting the gas lines of the volumetric gas separator and the calibrated measuring capacitance;

- significant dimensions of the device due to the presence of a calibrated measuring capacity and a volumetric gas separator, and with the growth of the gas factor (gas content per unit volume of oil), the dimensions increase;

- the complexity of manufacturing a calibrated measuring capacitance;

- the location of the calibrated measuring capacitance only perpendicular to the horizontal surface narrows the possibility of application on sites of limited dimensions and / or, if necessary, location among existing equipment;

- the content in the gas of suspended oil particles caused by the absence of a gas part, since after the volumetric gas separator the gas together with the suspended oil particles (in the form of droplets of spray and foam) immediately enters the gas line and therefore the suspended particles do not have time to settle;

- a large number of sensors and the need to use only level sensors (filling), hydrostatic and gauge pressures, as well as a thermometer and a timer, which excludes the possibility of applying for another method of measuring the amount of oil and gas based on the measurement of any other parameter except the level, hydrostatic and overpressure, as well as temperature and time.

The present invention is aimed at improving the accuracy of measurements and reducing their time, improving reliability and ease of use.

This is achieved by the fact that in a device for measuring the amount of oil and oil gas containing a separation device and pipelines for supplying an oil-water mixture, an outlet for oil gas and an oil-water emulsion, the container is made in the form of a column damped from the ends, the axis of the column is perpendicular or inclined to a horizontal surface, the pipeline for supplying the oil and gas mixture is connected to a separation device dividing the column into upper and lower parts, connected or not connected, the pipeline yes, an oil-water emulsion is connected to the bottom of the column, an oil gas outlet pipe is connected at the top of the column, an oil gas outlet pipe is equipped with a device for measuring the amount of oil gas, a device for measuring the amount of oil gas, one or more sensors are located in the column, while the diameters of the top and the lower parts are made equal or unequal, the lengths of the parts are made equal or unequal, while when the axis of the column is inclined to a horizontal surface, the angles n clone axes horizontal surface parts are made equal or unequal, axis portions are located in the same or in different planes perpendicular to the horizontal plane, and each part is made from one or more rectilinear pipes having different angles of inclination to the horizontal surface. In addition, the separation device is connected to the lower part of the column by means of a nozzle, the inlet and outlet of the nozzle being respectively located between the outlet of the pipeline for supplying the oil and gas mixture and the inlet of the pipeline for extracting the oil-water emulsion. In addition, in some cases, part of the nozzle is located outside the column, and the separation device is equipped with a unit for uniform distribution. In this case, one or more sensors are made with the possibility of axial and / or radial movement, a soothing element is located in the lower part of the column above the outlet of the nozzle, part of the oil gas removal pipeline can be made in contact with the column, and the column, separation device, as well as supply pipelines the oil-gas mixture and the removal of the oil-water emulsion and oil gas are fully or partially insulated. In addition, a device for removing asphalt-resin-paraffin deposits is provided, the column can be equipped with a frame, the separation device is made in the form of a truncated cone, the device for measuring the amount of oil gas is made in the form of a flow meter with a diaphragm, one or more sensors or level can be located in the column, or differential pressure, or hydrostatic pressure, or liquid flow meter, or pulse counter with the possible use of a calibrated hole, block for uniform distribution can be made in the form of a tube curved by a ring with slits, and the soothing element is made in the form of a perforated plate completely or partially overlapping the cross section of the column. In addition, the introduction of reagents against the formation of asphalt-resin-paraffin deposits may be provided.

The execution of the column plugged from below allows you to reduce the amount of oil-water emulsion needed to measure its quantity, as well as the amount of oil. The plug of the column can be made, for example, in the form of a cone or a truncated cone, directed with the tip down.

The column is mounted so that its axis is perpendicular or inclined to a horizontal surface. The slope of the column is necessary in some cases to increase the surface area of the section "oil-water emulsion - oil gas". If the axis of the column made of a straight pipe is perpendicular to the horizontal surface, then its cross section in a plane parallel to the horizontal surface represents a circle with an area

where D is the diameter of the column.

If the axis of the column made of a straight pipe is inclined to a horizontal surface, then its cross section in a plane parallel to the horizontal surface is an ellipse with an area

where φ is the angle of inclination to the surface.

Comparison of formulas (1) and (2) shows that S _φ> S at all φ <90 °, since in this case sinφ <1.

As you know, the larger the surface area of the “oil-water emulsion - oil gas” interface, the more intense is the release of oil gas dissolved in the oil-water emulsion. Therefore, it is not necessary to install the column vertically (perpendicularly) to a horizontal surface, sometimes it can be installed obliquely if it is necessary to increase the surface area of the “oil-water emulsion - oil gas” section.

The connection of the pipeline for supplying the oil-gas mixture to the separation device, for example, in the form of a truncated cone, allows the oil-gas mixture to be divided into a water-oil emulsion and oil gas, which allows to increase the separation intensity and thereby reduce the size of the device, shorten the measurement time and increase their accuracy. The separation device may have a transverse size or less, or equal, or more than the diameter of the column, depending on the parameters of the oil-gas mixture and the physico-chemical properties of oil, oil gas and water. The separation device may completely or partially overlap the cross section of the column.

The division of the column into the upper and lower parts allows the collection of water-oil emulsion in the lower part of the column, and oil gas in the upper part of the column, thereby reducing the possibility of mixing them, which leads to increased measurement accuracy. Additionally, the upper and lower parts can be made of pipes of different diameters, lengths, and tilt angles depending on the parameters of the oil and gas mixture and the physicochemical properties of oil, oil gas, and water.

The implementation of the upper and lower parts connected or not connected depends on the quality of separation of the oil-gas mixture in the separation device, as well as on the parameters of the oil-water mixture and the physicochemical properties of oil, oil gas and water. If high-quality extraction of all oil gas is ensured, then the upper and lower parts are best performed unbound, as this eliminates the possibility of mixing the oil-water emulsion and oil gas, which improves the accuracy of measurements. Otherwise, the connection between the upper and lower parts is carried out, for example, by blocking part of the cross section of the column with a separation device or using special jumpers for communication between them, which can be located both inside and outside the column.

The connection of the pipeline emulsion of oil-water emulsion to the bottom of the column is required to ensure the discharge of oil-water emulsion from the column.

The connection of the oil gas discharge pipe in the upper part of the column is required to ensure the removal of oil gas from the column.

Equipping the oil gas discharge pipe with a device for measuring the amount of oil gas, for example a flow meter with a diaphragm, is required for measuring the amount of oil gas. Note that the pipeline for the removal of oil gas before and after the device for measuring the amount of oil gas must be direct and provide a steady flow of oil gas. Typically, the length of the straight section to the device for measuring the amount of oil gas is at least 20 calibers and after - at least 5 calibers.

The location in the column of one or more sensors, such as level, pressure, hydrostatic pressure, etc., is necessary to measure the amount of oil. At the same time, the number of sensors, and not their type, is an essential sign. Using different sensors and measurement techniques, you can determine or measure the amount of oil-water emulsion and the amount of oil.

The type and number of sensors installed in the column depends on the chosen measurement procedure. Below are several options for how, using different sensors, it is possible to measure (determine) the amount of oil.

Before starting the measurements, a sample of the oil and gas mixture is taken. In laboratory conditions, the densities of oil ρ _n and water ρ _{in are} determined (for example, by separating a water-oil emulsion into oil and water in a centrifuge and subsequent weighing of oil and water samples) and the chemical composition of oil gas and the concentration of its components (for example, by chromatography).

The density of the oil-water emulsion ρ _e is determined as follows:

where n _in - watering, i.e. volume fraction of water [dimensionless quantity] in the oil-water emulsion; n _n is the volume fraction of oil [dimensionless quantity] in the oil-water emulsion.

Option 1.

[м³] и обводненность водонефтяной эмульсии. Сечения берутся в плоскостях, параллельных поверхности. Начинается подача водонефтегазовой смеси в колонну с количеством водонефтяной эмульсии, например объемным расходом водонефтяной эмульсии

[м³/с]. Когда уровень водонефтяной эмульсии достигнет входа в переходник, водонефтяная эмульсия начинает вытекать через переходник. Количество водонефтяной эмульсии, например объемный расход водонефтяной эмульсии

[м³/с], измеряются устройством для измерения количества водонефтяной эмульсии. Одновременно начинается отсчет времени τ [с].Before entering the oil-water emulsion drain pipe, an adapter is installed with a device located inside it for measuring the amount of oil-water emulsion, for example, a turbine, so that the oil-water emulsion can enter the oil-water emulsion drain pipe only through the adapter. Above the entrance to the adapter, a level sensor is installed. The volume of the column part between the level sensor and the entrance to the adapter is measured

[m ³ ] and the water content of the oil-water emulsion. Sections are taken in planes parallel to the surface. The flow of oil-gas mixture into the column begins with the amount of oil-water emulsion, for example, the volumetric flow rate of oil-water emulsion

[m ³ / s]. When the level of the oil-water emulsion reaches the entrance to the adapter, the oil-water emulsion begins to flow through the adapter. The amount of oil-water emulsion, for example, the volumetric flow rate of oil-water emulsion

[m ³ / s], measured by a device for measuring the amount of oil-water emulsion. Simultaneously, the countdown of time τ [s] begins.

, и таким образом измеряется количество водонефтяной эмульсии.If the filling of the column above the level of entry into the adapter does not occur, then this means that

, and thus the amount of oil-water emulsion is measured.

If all the oil-water emulsion entering the column does not have time to flow out through it, then

When the oil-water emulsion reaches the level sensor, the countdown stops, the time is remembered. Then the difference in volumetric (4) costs entering the column and the resulting oil-water emulsion is determined by the ratio:

Then, from formulas (4) and (5), we determine the volumetric flow rate of the oil-water emulsion entering the column.

The amount of oil, namely the volumetric flow rate of oil Q _n , we find as the product of the volumetric flow rate of the oil-water emulsion entering the column, by the volume fraction of oil (3):

Option 2

[м³] и обводненность водонефтяной эмульсии. Сечения берутся в плоскостях, параллельных поверхности. Начинается подача водонефтегазовой смеси в колонну и одновременно отсчет времени τ. Когда водонефтяная эмульсия достигнет датчика уровня, отсчет времени прекращается, время - запоминается. Тогда объемный расход поступающей в колонну водонефтяной эмульсии определим как отношение объема к времени его заполнения:The pipeline drainage of oil-water emulsions is made with the possibility of overlap. Above the entrance to the pipeline for the removal of oil-water emulsion, a level sensor is installed. The volume of the column part between the level sensor and the entrance to the adapter is measured

[m ³ ] and the water content of the oil-water emulsion. Sections are taken in planes parallel to the surface. The flow of oil-gas mixture into the column begins and simultaneously the countdown of time τ. When the oil-water emulsion reaches the level sensor, the countdown stops, the time is remembered. Then the volumetric flow rate of the oil-water emulsion entering the column is defined as the ratio of volume to time of filling:

The amount of oil, namely the volumetric flow rate of oil Q _n , we find from expression (6).

Option 3

In the column is installed a sensor for measuring the height (upper level) H _e [m] of the column of oil-water emulsion, for example a ruler. The cross-sectional area of the pipeline for the removal of oil-water emulsion F _o [m ² ] and the water content of the oil-water emulsion are measured. The supply of oil-gas mixture to the column begins. The height of the oil-water emulsion column is set at any level and measured. The volumetric flow rate of oil-water emulsion is determined by the well-known formula

where α - flow coefficient, g - acceleration of gravity [m / ^s2].

The amount of oil, namely the volumetric flow rate of oil Q _n , we find from expression (6).

Option 4

At the entrance to the oil drain pipe, a plug with a calibrated hole is installed. The remaining operations are carried out similarly to option 3.

Option 5

It is similar to options 3 and 4, only for measuring the liquid level a hydrostatic pressure sensor is used, which is installed in the lower part of the column. Hydrostatic pressure P _v [Pa]-water emulsions and water emulsion height column are interconnected as follows:

After the hydrostatic pressure is established constant, by the formula (9) we determine the height of the column of the oil-water emulsion. We find the volumetric flow rate of the oil-water emulsion from (8), and the volumetric flow rate of oil from (6).

In some cases, especially at high pressures of the oil and gas mixture, a differential pressure sensor can be used instead of a hydrostatic pressure sensor to reduce the measurement error.

Option 6

If the column is a straight pipe, then the amount of oil-water emulsion and oil can be determined as follows. A hydrostatic pressure sensor is installed. The pipeline for the removal of oil-water emulsion closes. Hydrostatic pressure measured at timings τ ₁ and τ _2. Then the change in the height of the column ΔH of the oil-water emulsion is determined from (9) as follows:

Then the volumetric flow rate of the oil-water emulsion is defined as the ratio of the product of the cross-sectional area of the column in a plane parallel to the surface (1) or (2) by the change in the height of the column of the oil-water emulsion (10) to the time of change:

The volumetric flow rate of oil is determined from (6).

Option 7.

Before entering the branch pipe of the oil-water emulsion, an overflow valve is installed. The volume of oil-water emulsion ΔV _e measured at each opening of the overflow valve is measured. A pulse counter is located on the overflow valve, triggering, for example, each time the overflow valve is opened or closed. The number of times the pulse counter N is measured for the time Δτ. Then the volumetric flow rate of oil-water emulsion will leave:

The volumetric flow rate of oil is determined from (6).

Other options for determining the amount of oil and oil-water emulsion can be given. From options 1-7 it can be seen that to achieve the desired result - measuring (determining) the amount (volumetric flow rate) of an oil-water emulsion and oil - can be achieved by using one or more different sensors, namely:

- volume flow sensor (for example, turbine) and level sensor (option 1);

- level sensor (option 2);

- height sensor - rulers (option 3);

- height sensor - ruler and calibrated hole (option 4);

- hydrostatic pressure sensor or differential pressure sensor and calibrated hole (option 5);

- hydrostatic pressure sensor (option 6);

- pulse counter (option 7).

It follows that an essential feature is the number of sensors used, and not their type.

The implementation of the diameters of the upper and lower parts equal or unequal depends on the parameters of the oil-gas mixture and the physicochemical properties of oil, oil gas and water. Obviously, the larger the diameter, the greater the capacity of a unit of length. Changing the diameter is necessary to ensure the required measurement accuracy at the lowest possible column height.

The fulfillment of the angles of inclination of the axes of the parts to the horizontal surface equal or unequal depends on the parameters of the water-oil and gas mixture and the physico-chemical properties of oil, oil gas and water. From formulas (1) and (2) it can be seen that the greater the angle of inclination, the greater, other things being equal, the height capacity. Changing the angle of inclination is necessary to ensure the required measurement accuracy at the lowest possible column height. This applies to both the upper and lower parts of the column.

The location of the axes of the parts in one or in different planes, perpendicular to the horizontal surface, while maintaining the accuracy of the measurements allows you to enter the column into existing equipment. This provides a reduction in the area occupied by the device.

The execution of each part from one straight pipe or from several straight pipes having different angles of inclination to a horizontal surface depends on the parameters of the oil and gas mixture and the physicochemical properties of oil, oil gas and water. This is determined by the requirement to maintain the accuracy of measurements with a unit length capacity, as well as to enable the device to fit into existing equipment, which will simplify its operation, in particular by reducing the service area.

The connection of the separation device with a pipe with the bottom of the column between the outlet of the oil-gas mixture supply pipeline and the inlet of the oil-water emulsion pipe allows filling the lower part of the column by supplying the oil-water emulsion during the greater part of the process below the level of the oil-water emulsion, which significantly reduces the possibility of foam or spray formation. This leads to an increase in the accuracy of measurements, and also allows to reduce fluctuations and waves on the surface of the oil-water emulsion in the lower part of the column, as well as to increase the intensity of the release of dissolved oil gas.

The location of the part of the pipe outside the column allows to reduce the asphalt-resin-paraffin deposits on the pipe, which will reduce their influence on the measurement accuracy, for example, of the current volume of the lower part of the column, since this volume decreases as the asphalt-resin-paraffin deposits increase.

Equipping the separation device with a unit for even distribution, for example, a tube with slits bent by the ring, allows the full and even use of the entire working surface of the separation device, which leads to an increase in the separation intensity and quality. This gives an increase in the accuracy of measurements and a decrease in the dimensions of the installation.

The implementation of one or more sensors with the possibility of axial and / or radial movement allows depending on the parameters of the oil-gas mixture and the geometry of the inner part of the column to reduce the time of measurements while maintaining their accuracy.

The location in the lower part of the column above the outlet of the nozzle of the soothing element, for example, in the form of a perforated plate completely or partially overlapping the cross-section of the column, allows to reduce fluctuations in the surface of the oil-water emulsion, which leads to increased measurement accuracy.

The execution of a part of the pipeline for extracting oil gas in contact with the bottom of the column improves the reliability of measurements at negative temperatures by heating from the bottom of the column, since the temperature of the oil-water emulsion is in most cases positive (in the fields of Western Siberia, the temperature of the extracted oil-water emulsion is often 50 ° C and above).

Additionally, to reduce the heat exchange of the device for measuring the amount of oil and oil gas with the environment, it is possible to completely or partially (depending on operating conditions, design, etc.) insulate the column, separation device, as well as pipelines for supplying the oil-gas mixture and for removing the oil-water emulsion and oil gas. This will increase the accuracy of measurements, because otherwise, at negative ambient temperatures, freezing of water, a change in the density of oil, water and oil gas, a change in the coefficient of evolution of dissolved oil gas, etc.

The use of a device against the formation of asphalt-resin-paraffin deposits allows to reduce the formation of asphalt-resin-paraffin deposits in the column and on its elements. This leads to improved measurement accuracy. As such a device, you can use, for example:

- the introduction of a reagent that prevents the formation of asphalt-resin-paraffin deposits (in the oil-water mixture or oil-water emulsion), by means of a device for introducing the reagent;

- a protective coating against asphalt-resin-paraffin deposits of the inner surface and column elements;

- placement inside the column of a removable block (plastic, cloth, metal, etc.) to collect asphalt-resin-paraffin deposits;

- the implementation of the column or its part with the possibility of heating, for example, by an electric heater to the melting temperature of asphalt, and / or resin, and / or paraffin;

- the location inside the column of cleaning elements (scrapers, ruffles, etc.) made with the possibility of axial and / or radial movement.

Equipping the column with a frame makes it possible to increase the reliability of the operation of the device, especially when located in swampy places and when snow melts, since it is possible to displace the soil. Additionally, a protective fence can be installed on the frame (both anti-vandal and weather protection), the fence can protect the entire device for measuring the amount of oil and oil gas, or the most important elements, depending on the needs.

In some cases, the inlet to the oil-water emulsion drain pipe may be equipped with a plug with a calibrated hole and / or a shut-off device, such as a valve. This will allow you to change the residence time of the oil-water emulsion in the lower part, which will increase the accuracy of measurements and expand the operating range.

To increase reliability during shutdown of the power supply, the valve must be used normally open.

The pipeline for supplying the oil-gas mixture is connected to the separation device, for example, directly or tangentially, which will ensure uniform distribution of the oil-gas mixture over the separation device, depending on the parameters of the oil-gas mixture. Elements for intensifying the separation of oil gas, for example, pins or twisting elements, the twisting direction of which coincides with the direction of twisting of the oil-gas mixture, can be located on the inner surface of the separation device.

In order to increase the residence time of oil gas in the upper part of the column, the inlet to the oil gas discharge pipe can be located at the farthest point from the separation device.

A computing device and a power source, if used to process and store measurement results, can be located in the ground below the depth of freezing of the soil. To heat them, you can sometimes use the heat of the oil and gas mixture, since the temperature of the production of oil wells in the vast majority of cases is positive.

A device for measuring the amount of oil and gas is shown in figure 1. A variant of the device for measuring the amount of oil and oil gas, providing a uniform distribution of the oil-gas mixture and reducing foaming, is shown in figure 2.

A device for measuring the amount of oil and oil gas includes a pipe for producing a well 1 with a valve 2. A pipe for supplying a water-oil mixture 3 with a valve 4 connected to a separation device 5 is connected to a pipe for supplying a production of well 1; a separation device 5 is located inside the column 6 and divides her on the lower 7 and upper 8 parts. The lower 7 and upper 8 parts of the column 6 in the shown case have equal diameters and angles of inclination of the axis to the horizontal surface, but different lengths. An oil-water emulsion 9 discharge pipeline with a valve 10 is connected to the bottom of the column 7. An emergency pipe 11 with an overflow valve 12 is connected to the oil-water emulsion 9 removal pipeline. An oil-water emulsion 9 discharge pipe and an emergency pipe 11 are connected to the pipeline for producing the well 1. To the upper part 8 columns 6 connected to the pipeline for the removal of oil gas 13, connected to the pipeline for the production of wells 1. The pipeline for removal of oil gas contains a device for measuring the amount of oil gas a 14 and valve 15. In the lower part 7, there is an upper level sensor 16. The separation device 5 partially blocks the cross section of the column 6. For uniform distribution of the incoming oil and gas mixture through the separation device 5, a unit for uniform distribution is designed 17. A nozzle 18 is connected to the separation device 5 .

нижней части 7 колонны 6 до датчика верхнего уровня 16. Закрывается клапан 2 и открываются клапаны 4 и 15, одновременно начинается отсчет времени заполнения τ_э. Клапаны 10 и 12 остаются закрытыми. Из трубопровода для подвода продукции скважины 1 водонефтегазовая смесь по трубопроводу для подвода водонефтегазовой смеси 3 начинает поступать в сепарационное устройство 5, где происходит ее деление на водонефтяную эмульсию и нефтяной газ. Под действием силы тяжести из сепарационного устройства 5 водонефтяная эмульсия поступает в нижнюю часть 7 колонны 6, а нефтяной газ - в верхнюю часть 8. Водонефтяная эмульсия собирается в нижней части 7 колонны 6. Когда водонефтяная эмульсия достигнет высоты срабатывания датчика верхнего уровня 16, отсчет времени прекращается. Объемный расход водонефтяной эмульсии определяется как отношение вместимости к времени заполнения по формуле (7), а количество нефти (объемный расход нефти) - по формуле (6). Из верхней части 8 колонны 6 нефтяной газ отводится по трубопроводу отвода нефтяного газа 13, в котором и осуществляется замер количества нефтяного газа с помощью устройства для измерения количества нефтяного газа 14. После завершения измерений клапан 10 открывается и водонефтяная эмульсия сливается из нижней части 7 колонны 6 по трубопроводу для отвода водонефтяной эмульсии 9. При нештатных ситуациях, например при повышении давления в колонне 6 выше расчетного, срабатывает (открывается) переливной клапан 12, и водонефтегазовая смесь отводится из колонны 6 по аварийному патрубку 11.A device for measuring the amount of oil and oil gas works as follows. A sample of the water-oil and gas mixture is taken using a sampler, which should be equipped with the wellhead equipment of each well. This sample measures the density of oil ρ _n and water ρ _c , as well as the water content of the water-oil emulsion n _c . Capacity measured

the lower part 7 of the column 6 to the upper level sensor 16. The valve 2 closes and the valves 4 and 15 open, at the same time, the countdown time τ _e starts. Valves 10 and 12 remain closed. From the pipeline for supplying the production of well 1, the oil-gas mixture through the pipeline for supplying the oil-gas mixture 3 begins to flow into the separation device 5, where it is divided into oil-water emulsion and oil gas. Under the influence of gravity from the separation device 5, the oil-water emulsion enters the lower part 7 of the column 6, and oil gas flows to the upper part 8. The oil-water emulsion is collected in the lower part 7 of the column 6. When the oil-water emulsion reaches the response height of the upper level sensor 16, the countdown ceases. The volumetric flow rate of a water-oil emulsion is defined as the ratio of capacity to filling time according to formula (7), and the amount of oil (volumetric flow rate of oil) is determined by formula (6). From the upper part 8 of column 6, petroleum gas is discharged through an oil gas discharge pipe 13, in which the amount of oil gas is measured using a device for measuring the amount of oil gas 14. After completion of the measurements, valve 10 opens and the oil-water emulsion drains from the lower part 7 of column 6 through the pipeline for removal of the oil-water emulsion 9. In case of emergency, for example, when the pressure in the column 6 rises above the calculated one, the overflow valve 12 is activated (opens) and the oil-gas mixture is discharged of column 6 through pipe 11 crashes.

In order to evenly distribute the oil-gas mixture over the separation device 5 and to ensure its more efficient use, a unit for uniform distribution is designed 17. The removal of the oil-water emulsion from the separation device 5 can in some cases be made through the pipe 18, which will reduce the possibility of foaming.

Note that in some cases, instead of the upper level sensor 16, you can use some other sensor or sensors (as shown above in options 1-7), for example, a hydrostatic pressure sensor. In the case of installing such a sensor (hydrostatic pressure) after establishing a constant column height of the oil-water emulsion, measurements are made according to option 7.

Thus, the claimed invention allows to increase the accuracy of measurements and reduce the time required for their implementation, as well as to increase the reliability of operation while simplifying use.

Claims (17)

1. A device for measuring the amount of oil and oil gas containing a tank, a separation device and pipelines for supplying an oil-water mixture, an outlet for oil gas and an oil-water emulsion, characterized in that the tank is made in the form of a column plugged from the ends, the axis of the column is perpendicular or inclined horizontal the surface, the pipeline for supplying the oil and gas mixture is connected to a separation device dividing the column into upper and lower parts, connected or not connected to each other, pipelines the water-oil emulsion outlet is connected to the bottom of the column, the oil gas outlet pipe is connected to the top of the column, the oil gas outlet pipe is equipped with a device for measuring the amount of oil gas, one or more sensors are located in the column, the diameters of the upper and lower parts being equal to or unequal, the lengths of the parts are made equal or unequal. 2. The device for measuring the amount of oil and oil gas according to claim 1, characterized in that when the axis of the column is inclined to a horizontal surface, the angles of inclination of the axes of the parts to the horizontal surface are made equal or unequal, the axis of the parts are located in one or in different planes perpendicular horizontal surface, and each part is made of one straight pipe or several straight pipes having different angles of inclination to the horizontal surface. 3. A device for measuring the amount of oil and oil gas according to claim 1 or 2, characterized in that the separation device is connected to the bottom of the column by means of a nozzle, the inlet and outlet of the nozzle being respectively between the outlet of the pipeline for supplying oil and gas mixture and the inlet of the pipeline for extracting oil-water emulsion . 4. A device for measuring the amount of oil and oil gas according to claim 3, characterized in that the part of the pipe is located outside the column. 5. A device for measuring the amount of oil and oil gas according to claim 1, characterized in that the separation device is equipped with a unit for uniform distribution of the mixture. 6. A device for measuring the amount of oil and oil gas according to claim 1, characterized in that one or more sensors are made with the possibility of axial and / or radial movement. 7. A device for measuring the amount of oil and oil gas according to claim 3, characterized in that in the lower part of the column above the outlet of the nozzle there is a soothing element. 8. The device for measuring the amount of oil and oil gas according to claim 1, characterized in that the part of the pipeline for extracting oil gas is made in contact with the column. 9. The device for measuring the amount of oil and oil gas according to claim 1, characterized in that the column, a separation device, as well as pipelines for supplying a water-oil mixture and a discharge of a water-oil emulsion and oil gas are made fully or partially heat insulated. 10. A device for measuring the amount of oil and oil gas according to claim 1, characterized in that a device is provided for removing asphalt tar and paraffin deposits. 11. A device for measuring the amount of oil and oil gas according to claim 1, characterized in that the column is equipped with a frame. 12. A device for measuring the amount of oil and oil gas according to claim 1, characterized in that the separation device is made in the form of a truncated cone. 13. A device for measuring the amount of oil and oil gas according to claim 1, characterized in that the device for measuring the amount of oil gas is made in the form of a flow meter with a diaphragm. 14. The device for measuring the amount of oil and oil gas according to claim 1, characterized in that the column contains one or more sensors or level, or differential pressure, or hydrostatic pressure, or a liquid flow meter, or a pulse counter with the possible use of a calibrated hole. 15. A device for measuring the amount of oil and oil gas according to claim 5, characterized in that the unit for uniform distribution of the mixture is made in the form of a tube with slots curved by the ring. 16. A device for measuring the amount of oil and oil gas according to claim 7, characterized in that the soothing element is made in the form of a perforated plate, completely or partially overlapping the cross section of the column. 17. A device for measuring the amount of oil and oil gas according to claim 1, characterized in that the input of reagents against the formation of asphalt-resin-paraffin deposits is provided.

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