RU2476733C1 - Bench for preparation of multicomponent water-gas-oil mixture for analysis - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: bench is designed for preparation of water-oil mixtures during tests of instruments for determination of concentration of oil or oil products in water, and can be used in factory laboratories and at enterprises, which design instruments for monitoring oil content in water, as well as during qualification of instruments for monitoring oil in water. Bench for preparation of multicomponent water-gas-oil mixture for analysis includes water and oil pumps connected with their suction branch pipes to water and oil tanks, and with their delivery branch pipes through flowmeters to a disperser connected via a water-gas-oil mixture outlet pipeline to a clarifying tank through a flowmeter and a mixture flow analyser; at that, it is equipped with an ejector installed in a tight cylindrical shell of the disperser, which is arranged on bearings with possibility of being rotated from a drive, and a gas tank connected via a pipeline through a flowmeter to a passive nozzle of ejector, to the active nozzles of which delivery branch pipes of pumps are connected, and flow divider outlets through valves; the inlet of the above divider is connected to the analyser outlet; at that, an additional pump is installed at the disperser outlet.

EFFECT: improving the accuracy of analysis of flow parameters of multicomponent mixture in the pipeline.

Description

The invention relates to pipeline transport, and in particular to devices for the preparation of gas and oil mixtures when testing devices for determining the concentration of oil or oil products in water, and can be used in factory laboratories and enterprises developing oil control devices in water, as well as in the certification of oil control devices in water.

A device for preparing a multicomponent mixture for analysis, including a jet mixer, is designed to increase the degree of homogeneity of the mixture by ensuring uniform distribution of the additive component over the entire cross section of the housing of the contact apparatus. SU 1152633 A, 04.30.1984.

A disadvantage of the known device is the turbulence of the fluid flow in the pipe, which persists after the fluid passes through the mixer.

A well-known stand for preparing a multicomponent mixture for analysis, containing water and oil pumps connected by suction pipes to water and oil tanks, and discharge pipes through flow meters to a disperser communicated by a water-gas mixture discharge pipe with a settling tank through a flow meter and an oil analyzer. SU 1593695 A1, 09/23/1990.

However, when changing the supply volumes of the additional gas component in the case of filling the apparatus with liquid, it is not possible to provide the required uniformity of the mixture and the given dispersion of gas bubbles. With an increase in the volume of supply of the additional product to the apparatus, the pressure in the distribution pipes increases and the structure of the supply of additional gas to the liquid medium changes.

The objective of the invention is to increase the degree of dispersion of oil particles to a size of less than 10 microns by ensuring uniform distribution of the additional gas component over the entire cross section of the housing.

The technical result achieved by the claimed invention is to increase the accuracy of the analysis of the parameters of the flow of a multicomponent water-gas-oil mixture in the pipeline.

The problem is solved and the technical result is achieved due to the fact that the stand for the preparation of a multicomponent gas-oil mixture for analysis contains water and oil pumps connected by suction pipes to water and oil tanks, and discharge pipes through flow meters to a disperser, connected by a pipeline of water-gas-oil mixture output with settling tank through the flow meter and the analyzer flow of the mixture, while new is that it is equipped with an ejector mounted in a sealed cylindrical body all dispersant placed on bearings with the possibility of rotation from the drive, and a gas tank connected by a pipeline through a flowmeter with a passive nozzle of the ejector, to the active nozzles of which are connected the discharge nozzles of the pumps and through the valves the outputs of the flow divider, the input of which is connected to the output of the analyzer, at the outlet of the dispersant, an additional pump is installed.

Figure 1 shows a diagram of a stand for preparing a multicomponent gas-oil mixture for analysis.

Figure 2 shows a schematic diagram of an ejector used in the proposed stand.

The stand for preparing a multicomponent water-gas mixture for analysis contains pumps 1 and 2 of water and oil, connected by suction pipes 3 and 4 to tanks 5 and 6 for water and oil, and discharge pipes 7 and 8 through flow meters 9 and 10 to dispersant 11, reported the pipeline 12 output of the gas-oil mixture with a settling tank 13 through the flow meter 14 and the analyzer 15 of the gas-oil mixture, while it is equipped with an ejector 16 mounted in a sealed cylindrical housing 17 of the dispersant 11, placed on bearings 18 with the possibility rotation from the drive 19. The drive 19 can be performed, for example, in the form of an electric motor. In addition, the stand contains a gas tank 20 communicated by the pipe 21 through the flow meter 22 with the passive nozzle 23 of the ejector 16, the discharge nozzles 7 and 8 of the pumps 1 and 2 are connected to the active nozzles 24 and 25 of the ejector 16. The stand also contains a flow divider 30, the outputs 31, 32 of which are connected by the hydraulic lines 33, 34 to the active nozzles 24 and 25 of the ejector 16. The input of the flow divider 30 by the hydraulic line 35 is connected to the output 36 of the analyzer 15. Moreover, the valves 37, 38 are installed in the hydraulic lines 33, 34, and in the hydraulic line 39, reporting output 36 of the analyzer 15 with a settling tank 13, also set copulating valve 40. In addition, at the outlet of the disperser 30 in the conduit 12 O vodogazoneftyanoy mixture an additional pump 41 is installed.

Fluid flow analysis is necessary for oil production from one or more wells. Typically, oil is produced from a well mixed with water and associated gas, thus producing a three-way fluid stream. Therefore, it is very important to be able to determine how much of the flow each component makes up.

The stand for the preparation of a multicomponent gas-oil mixture for analysis works as follows.

The corresponding parameters for temperature and salt concentration are set in the water tank 5, the pump 1 is turned on and the required water flow rate is set for the flowmeter 9, then the pump 2 is turned on and the predetermined oil concentration is set for the flowmeter 10. With pumps 1 and 2, water and oil in predetermined volumes are pumped through the active nozzles 7 and 8 to the active nozzles 24 and 25, and from them to the preliminary mixing chamber 26, as a result of which oil and water are crushed and a water-oil mixture is formed.

Then, under pressure, the oil-water mixture enters the working nozzle 27, and from it into the second mixing chamber 28, where the gas medium is ejected and the oil-gas mixture is finally mixed with the gas and the multicomponent gas-oil mixture is formed. With further movement of the flow through the mixing chamber 28, the flow velocity is equalized, then it enters the diffuser 29 of the ejector 16, where pressure increases and under a pressure of about 10 atm, the mixture enters the disperser body 17. When the disperser drive 19 is turned on, the housing 17 is installed in bearings 18, acquires an angular velocity, and the flow of the gas-oil mixture also acquires an angular velocity and swirls in the direction of rotation of the housing 17, thereby increasing the degree of mixing of the mixture and decreasing the possible gas delamination. The water-gas-oil mixture is discharged by the additional pump 41 through the pipeline 12 and the flow meter 14 into the gas-oil-gas mixture analyzer 15, where it is determined which part of the flow is made up of each of the components. After passing the gas-oil mixture of the analyzer 15 from its outlet 36, the flow of the gas-oil mixture can be directed to the settling tank 13. In this case, the valve 40 installed in the hydraulic line 39 is open, and the valves 37 and 38 are closed.

And also after passing the gas-oil mixture of the analyzer 15 from its outlet 36, the flow of the gas-oil mixture can be directed via a hydraulic line 35 to the inlet of the flow divider 30 and through open valves 37, 38 then to the active nozzles 24 and 25 of the ejector 16 for circulating the flow in a closed loop for increasing the degree of dispersion of oil particles to a size of less than 10 microns, while the valve 40 installed in the hydraulic line 39 is closed. A three-component flow of oil, water and associated gas flows through dispersant 11 and pipe 12. A temperature sensor measures the temperature of the stream, and pressure sensors transmit pressure measurements before and after dispersant 11 to the central data processing unit to calculate the pressure drop of the flow when passing through dispersant 11. Pulses of high and low power from the first block of gamma radiation after passing through the gas-oil mixture stream are received by a single detector of the first block of gamma radiation, processed and analyzed in a central data processing unit together with signals from a second gamma radiation unit installed at a certain distance along the flow from the first. The signals from the first gamma radiation unit are chronologically separated and grouped modulo for static analysis in the central data processing unit, which is a means for processing data and means for analyzing data that allows for accurate determination of the content of components in the gas-oil mixture stream. The second block of gamma radiation in combination with the signal from the first block makes it possible to calculate the flow rate, which, together with the value of the flow pressure drop, allows us to determine the general flow rate of the gas-oil mixture and the rate of consumption of individual components.

Information from the temperature sensor is necessary to take into account the compressibility of the gas fraction in the stream.

To determine the content of components in the mixture stream, various analysis tools are used. So, for example, means can be used to determine the type of flow, for example, layered or batch. For example, in batch flow, the relative contents of oil, water, and gas in individual portions and in a thin film between portions can vary significantly. It was found that with such stirring, a gas-oil mixture with a particle diameter of oil origin of less than 10 microns is obtained.

The size of the dispersant 11 may vary depending on the version. The length of the cylindrical body 17 of the dispersant 11, which gives the rotation of the gas-oil mixture, can be increased for a smoother flow of the gas-oil mixture.

Claims (1)

A stand for preparing a multicomponent water-gas-oil mixture for analysis, containing water and oil pumps connected by suction pipes to water and oil tanks, and discharge pipes through flow meters to a disperser, connected by a water-gas mixture output pipe with a settling tank, through a flow meter and a mixture flow analyzer, different the fact that it is equipped with an ejector installed in a sealed cylindrical disperser housing placed on bearings with the possibility of rotation from the drive, and the capacity for gas communicated by the pipeline through a flowmeter with a passive nozzle of the ejector, to the active nozzles of which are connected the discharge nozzles of the pumps, and through the valves the outputs of the flow divider, the input of which is connected to the output of the analyzer, while an additional pump is installed at the outlet of the dispersant.

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