RU2091579C1 - Method of taking samples of gas-liquid flow and device for its embodiment - Google Patents

Abstract

FIELD: oil producing industry; applicable in taking samples for determination of gas factor and production rate of wells. SUBSTANCE: created in zone of sampling are conditions for critical flowing of main flow and samples are taken from this zone with critical velocity of flowing of sampled flow. Critical conditions of flowing are created by installation of calibrated unions in the way of flows and taking sample into sampling tube from zone of critical effluent of main flow. EFFECT: higher efficiency. 4 cl, 4 dwg

Description

 The invention relates to the oil industry and can be used in the selection of particles (samples) of gas-oil flow coming from the well to the surface.

 The gas-oil flow sample taken is used to determine the gas factor and the flow rate of the wells, and the reliability of the determined values depends on the degree of its representativeness (identity to the main flow). The representativeness of the sample is determined by three main factors: the isokineticity of the main stream and the sample being taken, the homogeneity of the stream in the sampling zone and the pulsating mode of the well, and the duration of the sampling of the stream.

A known method of sampling for measuring the gas factor, including installing a pipe resistance with an axial channel in the pipeline, mixing the components of the gas-oil mixture in this channel and taking part of the mixture from it, as well as a device for implementing this method, including the pipeline and the fitting, channel installed in the pipeline which is made with a radial tap for sampling [1]
The known method and device create a sufficiently high homogeneity of the flow, but do not provide isokinetics of the main and selected flows.

A known method of sampling a gas-oil stream, which involves installing a multi-channel (multi-jet) pipe resistance in the flow path and draining one of the jets into the meter, as well as a device for implementing this method, comprising pipe resistance installed in the pipeline with channels of the same diameter, one of which communicates with sampling loop [2]
The disadvantages of the known method and device are the impossibility of sampling a sufficiently representative (identical to the main stream) sample, since in different channels the flows of the gas-liquid mixture are inhomogeneous in the quantitative ratio of gas and liquid, and the principle of isokinetic flows is not maintained due to various pressure gradients in channels.

Closest to the invention is a method of sampling a portion of a gas-liquid stream, comprising creating a homogeneous medium by intensively mixing the main stream and sampling under the isokinetic flow regime of the main and sample streams. A device for implementing this known method comprises a housing with an isokinetic probe placed therein and a flow turbulator in the form of a nozzle with a turbulent grating coaxially mounted in the housing [3]
The technical disadvantages of the known method and device are the insufficient homogenization of the gas-liquid medium and the difficulty in ensuring the isokinetic mode of flow, so it must be constantly monitored and maintained.

 An object of the invention is to provide a method for sampling a gas-liquid stream and a device for its implementation, which allows to increase the representativeness of the selected part of the gas-liquid stream, to ensure a high degree of homogenization of the gas-liquid mixture in the sampling zone, and to stabilize the isokinetic flow regime of the main and sample flows.

 The problem is solved in that when sampling a gas-liquid stream, including creating a homogeneous medium in the sampling zone and the isokinetic mode of flow of the main and sample flows, create a zone of critical flow of the main gas-liquid stream and sampling from this zone with a critical flow rate of the sample stream, while Critical flow regimes are created by installing fittings in their paths, at the inlet and outlet of which pressure is maintained, the ratios of which are not less than 1.6.

 The invention also lies in the fact that in the device for implementing this method, comprising a hollow body with channels for entering and exiting a gas-liquid stream and a sampling tube located in the cavity of the housing, subcritical fittings are installed in the housing and at the entrance of the sampling tube, while their passage sections are set so that they ensure the establishment of critical flow regimes of gas-liquid flows, and the sampling tube is placed so that the entrance to it (into the fitting installed in it) is in the critical zone expiration of the main gas-liquid stream.

 To quickly configure the device for any liquid and gas flow rates, the fittings can be interchangeable, and when working in wells equipped with sucker rod pumps, check valves must be installed in front of the fitting in the device body and in the sampling tube.

 In FIG. 1 shows a diagram of a device for implementing the method; in FIG. 2 - a device mounted in a borehole fitting; in FIG. 3 graphs of measurements of flow rate and gas content; in FIG. 4 is a graph for measuring flow rate at different distances of the sampling point from the zone of critical flow.

 The proposed method is based on the laws of motion of a gas-liquid system in the field of forces caused by the pressure drop across the narrowing devices of the nozzles. At subcritical nozzles, such as the fittings used in the oil and gas fields, the flow velocity at the exit of the nozzle is less than or equal to a critical velocity equal to the speed of sound at a given pressure and temperature. If at a given pressure drop the flow rate at the nozzle exit reaches a critical speed, then a further increase in pressure at the inlet does not lead to a change in speed. In this case, the so-called crisis of the current.

 As calculations and pilot tests of the device show, the critical velocity at the outlet of the nozzle is achieved under conditions when the ratio of the pressure at the inlet of the nozzle to the pressure at its outlet is equal to or greater than 1.6.

 The fact that the flow reaches a critical speed is easily verified in practice by changing the pressure at the inlet or outlet of the nozzle, respectively, by a central or manifold valve. If the flow rate (well flow rate) does not change when the pressure changes, then the critical outflow of the gas-liquid system is established on the nozzle.

By placing a sampling tube (probe) with a subcritical nozzle-nozzle in the region of the critical outflow of the gas-liquid system, it is possible to cut off a part of the stream, which in the nozzle will also move at a critical speed, that is, in the isokinetic mode with the main stream. In this case, the fraction of the selected part of the flow, which is determined by the ratio of the areas of the flow cross-sections of the nozzles, can vary over a wide range (0.5-10 ^-3 ) by changing the diameter of the nozzle in the sampling tube, thereby ensuring the required measurement time and the required volume of the measured liquid.

 The requirement of a homogeneous medium at the sampling point, as is known, is satisfied at a critical outflow of a gas-liquid system.

 The method is implemented by a device that ensures the passage of all borehole products through a calibrated pipe resistance (fitting) and containing a sampling probe with a shut-off valve and a removable fitting with a pointed end, which has a calibrated small diameter channel at the input section and a large diameter channel at the output section equal to or similar in diameter to the channel in the sampling probe.

 The device (figure 1) for sampling contains a housing 1, at the entrance to which a replaceable fitting 2 is installed, a channel 3, in which is a channel for the gas-oil flow to enter the cavity of the housing. The fitting 2 is selected based on the conditions for establishing in it a critical flow regime of the gas-liquid mixture. In the cavity of the housing 1, coaxially to the fitting 2, a sampling tube (probe) 4 is installed with a shut-off valve 5 through which it can be connected to a measuring separator and a gas meter.

 At the entrance to the sampling tube 4, a nozzle 6 is installed, which, like the nozzle 2, provides a critical mode of flow of the mixture. The location of the ends of the nozzles 2 and 6 in one plane ensures the installation of the inlet of the tube 4 in the zone of critical flow in the nozzle 2.

 In the housing 1, the tube 4 is introduced through a sealing threaded connection 7, which makes it possible to adjust the position of the nozzle 6 relative to the nozzle 2.

 To exit the gas and oil flow from the cavity of the housing 1, radial channels (holes) 8 are used. A device with a critical fitting is installed in the flow line 9 of the well through the seal 10 and is fixed with a threaded connection 11.

 The device can be mounted directly in the downhole fittings (Fig. 2). In this case, the well reinforcement is used as the housing 1. For ease of installation, the sampling tube is placed in a perforated pipe 12 connecting the fitting 2 to the flange 13.

 As a rule, at most production wells there are already working fittings that determine the mode of their operation. The working fittings are installed according to a scheme similar to that shown in Fig. 1, but in a housing muffled from the end.

 To enter the tube 4 at the end of the housing 1 make a hole, which during the operation of the well can be closed with a stopper.

 To assess the flow regime of the gas-oil mixture, buffer pressure (at the inlet to the nozzle) and linear (at the outlet of the nozzle) are measured. If the ratio of the measured pressures is higher than 1.6, then the working nozzle provides a critical flow flow, and representative sampling can be performed on all nozzles with a diameter equal to or less. If the pressure ratio is less than 1.6, then a smaller diameter fitting should be installed and the required pressure ratio achieved. The reliability of reaching the critical mode is checked by adjusting the linear pressure with a linear valve. If the increase in linear pressure within 0.2 0.4 MPa does not lead to a change in the measured flow rate, then the flow regime is critical.

 The method can be implemented as follows.

 When the shutoff valves of the well reinforcement are opened, the gas-oil flow enters the nozzle 2, at the outlet of which the critical flow rate is established, which ensures the homogeneity of the gas-oil mixture.

 When the valve 5 is opened on the nozzle 6, a critical pressure drop is provided and the isokinetic flow regime of the selected part (sample) of the gas-oil flow is established.

 Since the isokinetic flow regime with this sampling method is practically self-regulating, a high degree of representativeness of the samples is guaranteed.

 The selected part of the gas and oil flow is used to obtain data on the gas content of the products and the flow rate of the well.

 When connecting the tube 4 to the measuring separator, the gas content is determined by the ratio of the volume of gas passing through the gas meter to the volume of liquid in the separator.

 The liquid flow rate of a well is calculated by multiplying the volume of fluid that entered the measuring unit per unit time by the ratio of the passage area of the nozzle installed in the housing of the sampling device to the area of the passage section of the nozzle installed in the sampling pipe.

 The design of the device allows for wells that differ significantly in flow rate and gas content, to select a fitting with a diameter of the inlet channel for a sampling tube, which provides a representative sampling of a part of the well’s production for a given period of time for a given volume meter and operating characteristics of the gas meter.

 All of the above (in aggregate) provides a simplification of the method for obtaining a homogeneous medium at the sampling point and the isokinetic mode of sampling a part of the flow, increases the representativeness of the selected gas-liquid system and the reliability of measurements of gas content and flow rate of wells, and also extends the range of measured flow rates and gas contents.

 The graphs (figure 3) presents the results of pilot tests of the method and device.

Curve “A” for measuring the flow rate of the well was constructed according to the results obtained at well 1117 of the Tagrinskoye field, which worked at a nozzle of 6 mm with a flow rate of oil of 38 m ³ / day.

 The pressure at the wellhead was 55 atm and 9 atm in the collector line. The pressure at the outlet of the nozzle was changed by a collector valve to 50 bar. The results of measuring the flow rate and gas content (curve "B") by the device remained almost constant when the pressure at the outlet of the nozzle changed from 9 ati to 33 ati, which indicates a critical mode of flow of the gas-liquid mixture at the outlet of the nozzle. With a further increase in pressure (with a pressure ratio of less than 1.6), the outflow mode became subcritical and the results of measuring gas content and flow rate began to depend on pressure, which indicates a violation of the homogeneity of the system and the isokinetic flow regime in the nozzle and nozzle.

 Curve "B" (Fig. 4) is plotted based on the results of measurements of the flow rate of the well at different positions of the sampling point relative to the outlet cross-section of nozzle 2. The pressure at the inlet of the nozzle was 55 ati, at the output of 9 ati, i.e. under conditions of critical expiration of a gas-liquid mixture.

 In FIG. Figure 4 shows that when the sampling point is removed from the outlet cross section of the nozzle by more than 2.0 mm, the flow rate obtained by the device decreases due to a sharp drop in the density of the medium and flow rate, i.e. due to violation of the conditions for the isokineticity of the flow regimes of the main and selected flows and its homogeneity.

 Thus, the critical conditions for the reliability of the measurement results are the critical regime of the system outflow from the nozzle and the selection of a part of the flow in the critical flow zone.

 It is known that at the exit of a subcritical rectilinear nozzle in the so-called dead zone, as well as on the surface of the sampling device standing in the stream, vortex flows arise. In order to exclude the influence of edge effects on the measurement results of the fittings, it should have sharp edges with a smoothly changing profile and be installed along the central axis of the fitting 2, which is achieved by installing a centralizer 14.

 With large pressure drops at the wellhead and in the collector line, the perforated pipe 12 can be crushed (Fig. 2), and therefore it can be reinforced with stiffeners.

 The device allows you to select a representative part of the flow and measure the flow rate of fountain and gas lift wells, as well as wells equipped with electric centrifugal pumps.

 In wells with sucker rod pumps, the pressure drop across the nozzle varies over a wide range in each cycle, and part of the time the pressure drop across the nozzle may turn out to be less than critical, which does not allow obtaining the correct results of measuring the flow rate and gas content of the product.

 To ensure measurements in the critical mode of flow of the main and sampled parts of the flow, check valves are installed in front of the nozzle and in the sampling tube in the collector line, which shut off the flows when the pressure drop is less than critical.

Claims (4)

 1. A method of sampling a gas-liquid stream, including creating a homogeneous medium in the sampling zone and the isokinetic flow regime of the main and sample streams, characterized in that they create a critical zone of the main gas-liquid stream and sampling from this zone with a critical flow rate of the sample stream, in this case, critical flow regimes of the main and selected flows are created by installing fittings in the flow paths.  2. A device for sampling a gas-liquid flow, comprising a hollow body with channels for inlet and outlet of the stream and a sampling tube located in the cavity of the housing, characterized in that the fittings are installed in the housing and at the entrance to the sampling tube, while the passage sections of the fittings are set so that ensure the establishment of critical flow regimes of gas-liquid flows, and the sampling tube is placed so that the entrance to it is in the zone of critical expiration of the main gas-liquid flow.  3. The device according to claim 2, characterized in that it is equipped with check valves installed in the housing in front of the fitting and in the sampling tube.  4. The device according to p. 2 or 3, characterized in that the fittings are removable.

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