RU2485453C2 - Method to determine working parameters of gas-liquid flow in pipeline and device for its realisation - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: gas-liquid flow is sent via a pipeline and its section, on which a device is installed to measure flow parameters and/or a sampling device, and flow parameters are defined using these devices, or a sample is taken for analysis. Besides, in the section of the pipeline upstream the device of parameter measurement by flow or composition of the flow or the sampling device, pressure is increased. The device represents a section in the pipeline for separation of the flow into gas and liquid at the specified pressure with further separate transportation of phases by pipeline branching - a section for gas transportation and a section for liquid transportation with the installed device for liquid flow parameters definition or the device of sampling from any phase for further definition of parameters by analysis of sample parameters, combination of these devices. The section in the pipeline, where the flow is separated into gas and liquid phases with pressure of saturated vapours of more than 500 mm of mercury column, and the section in the pipeline, where the device is installed for definition of parameters by the flow or composition of the flow or for sampling, are installed along with the flow downstream the stage of separation at elevations providing for definition of liquid parameters and sampling at the pressure exceeding the pressure of flow separation into phases.

EFFECT: increased efficiency of flow parameters definition and provision of high accuracy with quantitative and qualitative accounting of liquid pumped along a pipeline.

8 cl, 1 dwg

Description

The invention relates to a technology and technique for determining the parameters of a gas-liquid flow in a pipeline and can find application in oil and other industries where high accuracy in determining the parameters of a gas-liquid flow in a pipeline is required.

A known method for determining the parameters of a gas-liquid flow in a pipeline, in which a gas-liquid flow is passed through a filter (s), a device for measuring flow parameters (s) or along a section (s) of a pipeline on which (s) is located means (s) for measuring flow parameters and (or) a device for sampling for subsequent determination of flow parameters by analyzing sample parameters, analyze flow parameters [1].

A device for implementing this method is known, which is a section of the pipeline on which the device (s) are installed for determining flow parameters or sampling for subsequent determination of flow parameters by analyzing sample parameters [2].

A disadvantage of the known techniques and technologies for determining the parameters of a gas-liquid flow in a pipeline is the low representativeness of the sample, the accuracy of determining the flow parameters by devices for determining the parameters during its separation. The low quality of the sample and the accuracy of determining the flow parameters by the devices for determining the parameters are due to the stratification of the flow due to the difference in the density of the liquid and gas, the enlargement of gas particles and inclusions under the influence of van der Waals forces and turbulence of the flow and the influence of gravity on the flow.

A known method for determining the parameters of a gas-liquid stream in a pipeline, in which a gas-liquid stream is passed through a mixing device, filter (s), a device for measuring parameters (s), means (s) for measuring flow parameters and (or) a device for sampling for subsequent determination flow parameters by analyzing the sample parameters, carry out the analysis of flow parameters [3] (prototype method).

A device for implementing this method is known, which is a section of the pipeline on which a mixing device, filter, device (s) are installed for determining flow parameters or sampling for subsequent determination of flow parameters by analyzing sample parameters [4] (prototype device).

A disadvantage of the known techniques and technologies for accounting for gas-liquid flow in the pipeline is the low representativeness of the sample, the accuracy of determining the flow parameters by devices for determining the parameters during its separation. The low quality of the sample and the accuracy of determining the flow parameters by the devices for determining the parameters are due to the stratification of the flow into phases, the formation of flow heterogeneity, which occurs due to the remoteness of the device for determining flow parameters or sampling from the mixing device, a decrease in pressure in the pipeline as a result of loss of pressure head and process intensification phase separation of the flow due to an increase in gas volume.

The technical result of this invention is to increase the accuracy of determining the parameters of the gas-liquid flow in the pipeline.

To achieve a technical result in a method in which a gas-liquid stream is passed through a pipeline and its section (s) on which (s) a device (s) for measuring flow parameters and / or a device for sampling are installed, carry out the determination of flow parameters using these devices and (or) take a sample for analysis, according to the invention, increase the pressure in the pipeline section in front of the flow meter or flow meter or the sampling device, that is, create an additional daily pressure. In this case, if there is a flow separation section on the pipeline, the pipeline section on which the devices used to determine the flow parameters by flow rate or composition of the flow are installed, are located along the flow after separation, while the sections are located relative to each other at levels providing determination of the liquid parameters or sampling at a pressure above the pressure of separation of the flow into phases. In this case, in the case of the passage of the flow through the filter and the mixing of the flow, the mixing device is installed along the flow after the filter. In this case, the mixing of the flow is carried out by a mixing device with a flow area greater than the flow area of the pipeline at the mixing site.

In the inventive method, the increase in pressure in the pipeline, where they are located in a different combination or separately: a measuring device or sampling device; measuring instrument and sampling device; measuring instrument; the sampling device, that is, regardless of which of these devices we place, allows us to reduce the density difference between the gas and liquid phases of the flow and thereby provide a better condition for mixing the flow under the influence of the turbulence of the latter, while with any alternative combinations of devices used for determine flow parameters. As a result, both (and) sampling, and (or) determination by means of measuring parameters, as from a more uniform flow, will provide the same technical result, namely a more accurate determination of its parameters, that is, regardless of alternative combinations of operations of the claimed a method for determining flow parameters. Therefore, due to the increase in pressure in the pipeline section where the flow parameters are measured or the sample is taken, and this operation is carried out with any alternative feature, any combination of features that is possible according to the claimed technical solution, will allow for the claimed method to increase the accuracy of determining quantitative and qualitative parameters flow compared with the determination of flow parameters by the prototype method [3], that is, to get the same technical result when combining each of the alter the native characteristics of one feature with each of the alternative characteristics of the other features separately for the proposed method. The implementation of the mixing of the pipeline flow after the filter and with an area of the cross-sectional area larger than the area of the pipeline cross-section in the mixing section provides better cleaning of the flow, and, therefore, contributes to less pollution of devices designed to determine the flow parameters, and also creates conditions for mixing that prevent gas evolution from the stream. This further increases the advantages of the proposed method compared to the prototype [3].

Thus, the implementation of the above operations of the proposed method will allow, in comparison with the method of the prototype [3] to increase the accuracy of determining the quantitative and qualitative parameters of the flow.

The application of the proposed method will allow a more accurate analysis of the flow parameters due to the selection of a more representative sample, and more accurately determine the flow parameters by means of measurements installed on the pipeline.

To achieve a technical result in the implementation of the proposed method, a device is used, which is a section on the pipeline for separating the flow into gas and liquid, followed by separate transportation of phases by branching the pipeline — a gas transportation section and a liquid transportation section with device (s) installed on them ) to determine the parameters of the fluid flow and, if necessary, the device (s) for sampling from any phase for the subsequent determination of the parameters by analysis and sample parameters according to the invention on the pipe portion, which stream is separated into a gas and a liquid phase with the vapor pressure more than 500 mmHg and the portion on the pipeline on which the device (s) are installed to determine the parameters for the flow rate and composition of the stream or for sampling, or a combination of them, is placed along the stream after the separation stage, while at the levels (heights) that ensure the determination of liquid parameters and sampling at a pressure higher than the phase separation pressure of the stream. In this case, the flow separation section is located above the section where the devices used to determine the flow parameters or sample collection are installed on the pipeline, at least 7 meters. Moreover, when one of the phases of the filters and the mixing device are used in the metering device, the latter is installed along the flow phase after the filter, while the passage of the mixing device is chosen not less than the area of the pipeline passage for transporting the corresponding phase.

The increase in pressure in the device on the pipeline section, where and / or continuous determination of the flow parameters by devices for determining flow parameters, and / or sampling by the device for sampling (to determine flow parameters in laboratory conditions) reduces the difference in the densities of the gas and liquid phases, which is especially important when the pressure of saturated vapors in a liquid is more than 500 mm Hg, when conditions arise in the flow for the liberation of free gas. As a result of this, under the influence of flow turbulence, the homogeneity of the distribution of inclusions in the pipeline flow is leveled, the accuracy of the parameters determined by the devices increases, and the representativeness of the samples taken by the sampling device also increases (for determining the flow parameters in laboratory conditions), that is, the claimed device allows to obtain the same technical the result when combining each of the alternative characteristics of one attribute with each of the alternative nature Stick other attributes apart for the claimed device. In the prototype device, the determination of parameters occurs without increasing the pressure in the pipeline compared to the separation pressure. As a result, due to the inevitability of reducing the pressure loss due to local friction losses with the pipeline, internal losses in the flow, the pressure in the pipeline drops and the determination of flow parameters in the pipeline occurs at a lower pressure than the pressure of separation of the flow into phases. A decrease in pressure in the flow leads to an increase in the volume of the gas phase up to the release of free gas from the liquid. Therefore, the determination of parameters using the prototype device [4], in contrast to the claimed one, will occur with greater heterogeneity, and hence with less accuracy. Therefore, due to the implementation of the listed features of the claimed device, the determination of the flow parameters using the inventive device will be more accurate with any alternative combinations of the devices used to determine the flow parameters and will provide the same technical result than using the prototype device [4].

As a rule, the pressure drop after separation of the flow to the section on the pipeline where the devices used (directly or indirectly) to determine the flow parameters are installed is at least 0.05 MPa. This pressure value corresponds to a difference of at least 7 m in height at the location levels of the flow separation section (s) and the pipeline section on which the devices for determining flow parameters are installed. Therefore, in the inventive device highlighted this feature, which is necessary to ensure the advantages of the claimed device over the prototype [4]. Also, the mixing of the pipeline flow after the filter and with the passage cross-sectional area of the mixing device with a larger cross-sectional area of the pipeline in the mixing section provides better cleaning of the flow, and, therefore, will contribute to less pollution of devices designed to determine flow parameters, as well as create conditions for mixing preventing the release of gas from the stream. This further increases the advantages of the claimed device compared with the prototype [4].

As a result, the determination of flow parameters using the inventive device compared to the prototype [4] will be more accurate and efficient.

Thus, due to the implementation of the inventive device according to its defining features, they will more accurately determine the flow parameters, including the selected sample (in contrast to the prototype device [4]).

The inventive method for determining the parameters of the gas-liquid flow in the pipeline and a device for its implementation from the pipeline can be specifically applied, for example, in oil fields - at commercial oil metering stations.

The inventive method for determining the parameters of the gas-liquid flow in the pipeline is as follows.

The gas-liquid flow is passed through the pipeline and its section (s), on which (s) the device (s) for measuring the flow parameters and (or) the device for sampling are installed, the flow parameters are determined using these devices and (or) a sample is taken for analysis, the pressure is increased in the pipeline section in front of the measuring device or sampling device, that is, an additional overpressure is created; in this case, in the case of passing the stream through the filter and performing mixing of the stream, the mixing device is installed along the stream after the filter; wherein the mixing of the flow is carried out with an increase in the flow cross sections in the local section of the pipeline and the mixing device.

The invention is illustrated by the drawing, presented in figure 1, is a diagram of the determination of flow parameters and a special case of the claimed device.

A device for determining the parameters of gas-liquid flow in the pipeline, figure 1, includes a section 1 of the pipeline for separating the flow into gas and liquid; branching of section 1 of the pipeline, - pipeline 2 for transporting gas and pipeline 3 for transporting liquid with flow meters 4 and 5 installed on them to determine the flow rate of gas and liquid, respectively; mounted on the pipeline 3 device 6 for sampling a liquid, a filter 7 and a mixing device 8; wherein the filter 7 and the mixing device 8 are installed sequentially along the flow in the order of their listing in front of devices 5 and 6; while section 1 of the pipeline for separating the flow into gas and liquid and section 9 of the pipeline 3, on which the listed devices 5-8 are installed, are placed at levels whose height difference provides pressure in section 9 of the pipeline 3, which is higher than the pressure of separation of the stream into gas and fluid in section 1 of the pipeline.

The device shown in Fig. 1 is intended for determining the parameters of a gas-liquid flow in a pipeline, while section 1 of the pipeline is intended for separation - dividing the flow into phases (gas and liquid) - and for separately passing gas and liquid flows through pipelines (directions, sections ) 2 and 3. The flow meter 4 is used to determine the flow rate of gas sent to the pipeline 2 after separation of the flow in the pipeline in section 1; devices 7-8, 5-6, respectively, are used for filtering, mixing, determining the flow rate and sampling the fluid from the pipeline 3 in section 9. Sections 1 and 9 of the pipeline are located at levels that provide an increase in pressure in the pipeline 3 in section 9. When this device for mixing the liquid 8 is designed from the condition of mixing the liquid with the passage section of the device 8, which corresponds or exceeds the area of the passage section of the pipeline 3.

A device for determining the parameters of gas-liquid flow in the pipeline, figure 1, works as follows.

The gas-liquid flow is directed through the pipeline to section 1, where the flow is separated at a given pressure for gas and liquid. After separating the flow into phases from section 1, gas is sent through pipeline 2, liquid is transferred through pipeline 3, and the flow parameters are determined: gas flow through pipeline 2 is determined by flow meter 4, liquid flow through pipeline 3 is determined by flow meter 5. Moreover, before determining the flow rate of the liquid using the flow meter 5, the stream is filtered and mixed, passing it through the filter 7 and the mixing device 8, respectively. Additionally, to determine the parameters of the liquid from the pipeline 3, select OCU by the device 6 for taking a liquid sample, which is then sent for analysis. Due to the location of the pipeline section 1 for separating the flow into gas and liquid with respect to the section 9 of the pipeline 3 for transporting the separated liquid, provided that the parameters of the separated liquid are determined using devices 5-8 at a pressure higher than the pressure of the flow separation in the pipeline section 1, the determination of the parameters of the separated liquid is not accompanied by the release of residual gas in the liquid, which means that it occurs without disruption of the mixing device 8, the flow meter 5 and the device Twa 6 for sampling the liquid. The operation of the mixing device 8 does not lead to the formation of free gas (after mixing) and, as a consequence, the malfunctioning of devices 5, 6 and 8 as a result of the absence of a sharp pressure drop during mixing, is ensured by the choice of the passage section of the device 8 according to areas corresponding to or exceeding the cross-sectional area of the pipeline 3. Thus, the use of a mixing device 8 contributes to an even more accurate determination of the parameters of the gas-liquid flow using roystva, 1.

For testing, a device was used to determine the parameters of the gas-liquid flow in the pipeline, figure 1, with the following parameters.

The prototype device [4] was similar to the one declared with the difference that the location level of section 1 of the pipeline and section 9 of pipeline 3 was the same, and for the claimed technology, section 1 was higher than section 9 by 12 m. The gas-liquid flow was a gas-oil mixture with a flow rate 11-50 t / h, gas content in the stream before separation (dissolved gas + free gas) = 84 m ³ / m ³ . The pressure in the pipeline during separation in section 1 was 0.5 MPa and was the same for the compared technologies, the pressure in the section of the pipeline in section 9 for oil (pipeline 3) was 0.6 MPa for the claimed technology and 0.42 MPa for the prototype technology [3-4].

If during comparative tests the gas meter showed the same results for the compared technologies, then the liquid meter 5 using the known technology [3-4] showed an oil consumption of more than 5% less than using the claimed technology, despite the fact that the oil passed through the mixing device 8, the volume of oil taken through the sampling device 6 was 15% less, and the water content was almost 12% less than by the claimed technology. Since the pressure according to the prototype technology [4] was less than the pressure during separation in section 1 of the pipeline, it is natural that in pipeline 3 for the prototype technology [3-4], residual gas continued to be actively released after section 1 of the pipeline. The presence of gas in the oil flow using the prototype technology [3-4] leads to a rapid separation of the flow and disruption of the mixing device 8, flow meter 5 and device 6 for sampling liquid. The test data clearly demonstrate that the determination of the parameters of the gas-liquid flow will be more accurate for the claimed technology. Thus, the test results confirm the advantage of the claimed technique for determining the parameters of the gas-liquid flow in the pipeline compared to the prototype [3-4] - the accuracy of the calculation of fluid flow is ensured by eliminating gas generation at the stage of determining the flow parameters due to the increase in pressure during operations aimed at determining the parameters gas-liquid flow in the pipeline.

The inventive selection method for determining the parameters of gas-liquid flow in the pipeline and a device for its implementation are industrially applicable - the necessary change in the reconstruction of the pipeline can be carried out by the manufacturers serving pipelines and metering units of gas-liquid flows in the pipelines.

Information sources

1. A method for determining the parameters of a gas-liquid flow in a pipeline and a device for its implementation / GOST 2517-85 with a change No. 1, Fig. 15b.

2. Device for determining the parameters of gas-liquid flow in the pipeline for sampling liquid from the pipeline / GOST 2517-85 with a change No. 1, Fig. 15b.

3. A method for determining the parameters of a gas-liquid flow in a pipeline and a device for its implementation / V.P. Tronov, Oil Field Processing. M., Publishing House "Nedra", Fig.1a, p.14.

4. Device for determining the parameters of a gas-liquid flow in a pipeline for sampling liquid from a pipeline. / V.P. Tronov, Oil Field Preparation. M., Publishing House "Nedra", Fig.1a, p.14.

Claims (8)

1. A method for determining the parameters of a gas-liquid flow in a pipeline, in which a gas-liquid flow is passed through the pipeline and its portion on which a device for measuring flow parameters and / or a device for sampling is installed, the flow parameters are determined using these devices or a sample is taken for analysis , characterized in that in the pipeline section in front of the device for measuring the parameter by flow rate or composition of the stream or the device for sampling increase the pressure. 2. The method according to claim 1, characterized in that if there is a flow separation section on the pipeline, the pipeline section on which the devices used to determine the flow parameters by flow rate or composition of the stream are installed is positioned along the stream after separation, while the sections are positioned relative to each other at levels that ensure the determination of fluid parameters or sampling at a pressure higher than the pressure of separation of the flow into phases. 3. The method according to claim 1, characterized in that in the case of the passage of the stream through the filter and the mixing of the stream, the mixing device is installed along the stream after the filter. 4. The method according to claim 3, characterized in that the mixing of the flow is carried out by a mixing device with a flow area greater than the flow area of the pipeline at the mixing site. 5. A device for determining the parameters of a gas-liquid flow in a pipeline, which is a section on the pipeline for separating the flow into gas and liquid at a given pressure, followed by separate transportation of phases by branching the pipeline — a section for transporting gas and a section for transporting liquid with a device for determining the parameters of the fluid flow or a device for sampling from any phase for subsequent determination of the parameters by analyzing the parameters of the sample , a combination of these devices, characterized in that the section on the pipeline, on which the flow is separated into gas and liquid phases with a saturated vapor pressure of more than 500 mm Hg, and the section on the pipeline, on which the device is installed to determine the parameters for flow or composition flow or for sampling, is placed along the flow after the separation stage, while at heights providing determination of the liquid parameters and sampling at a pressure higher than the phase separation pressure of the flow. 6. The device according to claim 5, characterized in that when one of the phases of the filter and the mixing device are used in the metering device section, the latter is installed along the flow phase after the filter. 7. The device according to claim 6, characterized in that the passage area of the mixing device is chosen not less than the area of the passage of the pipeline for transporting the corresponding phase. 8. The device according to claim 5, characterized in that the flow separation section is located above the section where the devices used to determine flow parameters or sample collection are installed on the pipeline for at least 7 m.

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