RU2492322C2 - Device to measure product yield of oil and gas producing wells - Google Patents

Abstract

FIELD: oil and gas industry.

SUBSTANCE: device comprises an input pipeline, a separator with a float, mechanically connected with a gate valve, a gas pipeline with an installed gate valve, a high-limit gas counter and a two-way pneumatically controlled valve. The valve is equipped with position fixators and a membrane chamber. The liquid pipeline is equipped with a liquid counter and the same valve. The plus cavity of the valve chamber on the gas pipeline is pneumatically connected with the same pipeline - with its cavity between the gate valve and the valve. Valve position fixators are adjusted so that values of pressure drop, which open and close the valve on the gas pipeline, are less than appropriate values of pressure drop, which open and close the valve on the liquid pipeline.

EFFECT: simplified design, expansion of functional capabilities and improved consumer properties.

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Description

The invention relates to the field of oil production and can be used in measuring the flow rate of a water-oil mixture (liquid) and associated petroleum gas (gas) produced from wells.

A device for measuring the flow rate of wells is known, which includes an inlet pipeline, a gas-liquid separator (separator), pipelines designed to drain liquid and gas from the separator, and an outlet pipeline.

A gas damper is installed on the gas discharge pipe (gas pipeline), which, together with the float mechanically connected to it, with which the separator is equipped, plays the role of a liquid level regulator in it.

A high-limit liquid meter is installed on the pipeline that drains the liquid from the separator (liquid pipeline), which works in conjunction with a differential pressure regulator - a two-position pneumatically controlled valve (valve), which ensures this meter operates in a certified range of flow values (therefore it is also sometimes called a flow regulator).

The valve is equipped with position locks (“open” - “closed”) and a membrane chamber (chamber), the submembrane (plus) cavity of this chamber being pneumatically connected to the upper separator cavity, and the supmembrane (minus) cavity of this chamber being pneumatically connected to the gas riser at the outlet the pipeline.

The device operates as follows.

The gas-liquid mixture enters the separator and is separated into gas and liquid.

Gas passes through the open damper to the outlet pipe, and the liquid accumulates in the separator (in the initial position, the valve is closed).

As the liquid level rises, the float covers the damper, as a result of which increased resistance to gas passage through it is created and in the separator (respectively, and in the positive cavity of the valve chamber), pressure relative to the outlet pipe begins to increase - pressure drop.

After closing the damper, when the gas pressure drop reaches the upper threshold of the valve, its shut-off element abruptly switches from the “closed” position to the “open” position and is fixed in this position.

After opening the valve, the liquid under the action of a differential pressure is intensively pushed out of the separator, the meter measures its quantity, its level in the separator begins to decrease.

As the liquid level decreases, the float opens the damper, the gas again begins to flow into the outlet pipe, and the pressure drop decreases.

When the pressure drop reaches the lower threshold of the valve, it also closes sharply, the liquid meter stops and the cycle of measuring the flow rate of the liquid ends.

Further, the process continues as described above.

Thus, the device allows using extremely high meter to measure extremely small flow rates.

A disadvantage of the known device is the limited functionality: the device allows measurements of the flow rate of only one component - liquid.

A device [2] is also known, which also includes an inlet pipeline, a separator with a float mechanically connected to the valve on the gas pipeline, a high-limit liquid meter, a two-position pneumatically controlled valve on the liquid pipeline, and an outlet pipeline.

However, the structure of this device further includes another gas pipeline, the same valve and throttle installed on the additional gas pipeline, and a high-limit gas meter installed on the main gas pipeline.

The minus cavities of the chambers of both valves are pneumatically connected to the gas riser in the outlet pipe, and the positive cavities of the chambers are connected to the upper cavity of the separator.

The device allows measurements of the flow rate of not only liquid, but also gas.

A disadvantage of the known device is the weak functional load of the nodes, the consequence of which is the complexity of the design, hardware redundancy, the narrowness of functionality and consumer properties.

In this regard, it should be noted that real measuring devices, which are based on the known device, due to their considerable cost, are manufactured in a group version.

Those. The known device is a measuring module, to which, with the help of a distribution module in automatic mode, up to 14 oil and gas producing wells located in the nearest district are alternately connected.

The choice of wells for connection to one installation on a territorial basis provides the lowest costs for the development of oil fields.

However, this leads to the fact that wells with a large gas flow rate (for example, up to 60,000 m ³ / day) and with very small (within 100 m ³ / day) are usually connected to one installation.

A disadvantage of the known device is its non-adaptability to the conditions of the object, which consists in the fact that when connecting wells with a gas flow rate below the meter sensitivity limit, this gas freely flows into the outlet pipeline and is not taken into account.

Another disadvantage of the known device is the design complexity - the presence of elements with an extremely low functional load, which results in an increased cost of real products made on its basis.

The aim of the invention is to simplify the design, expand the functionality and improve consumer properties.

This goal is achieved by the fact that in the device for measuring the production rate of oil and gas wells containing an inlet pipe, a separator with a float mechanically connected to the valve, a gas pipeline on which this valve is installed, as well as a high-limit gas meter and a two-position pneumatically controlled valve equipped with clamps position and a membrane chamber, a liquid pipeline equipped with a high-limit liquid meter and the same valve, and an outlet pipeline (moreover, whisker cavities of the chambers of both valves are also pneumatically connected to the gas riser in the outlet pipeline and the positive cavity of the valve chamber in the liquid pipeline is also pneumatically connected to the upper separator cavity), the plus cavity of the valve chamber in the gas pipeline is pneumatically connected to the same pipeline - with its cavity between the shutter and the valve, and the valve position locks are adjusted so that the differential pressure values at which the valve opens and closes on the gas pipeline de, less than the corresponding differential pressure values at which the valve on the liquid pipe opens and closes.

Comparison of the claimed solution not only with the prototype, but also with other technical solutions in this area, did not allow us to identify in them the features that distinguish the claimed solution from the prototype, which allows us to conclude that the criterion of "significant differences".

Comparative analysis with the prototype shows that the inventive device for measuring the flow rate of oil and gas production wells differs in that the connection of the positive cavity of the valve chamber on the gas pipeline to the same pipeline - to its cavity in the area between the valve and the valve and setting the valve position locks in such a way that the differential pressure values at which the valve in the gas pipeline opens and closes are less than the corresponding differential pressure values at which the valve opens and kryvaetsya valve in the liquid line, allows to measure the flow rate (amount) of gas regardless of its flow rate, i.e., increases adaptability to the conditions of the object and improves consumer properties of products made on the basis of the claimed device.

Thus, the claimed device for measuring the flow rate of oil and gas production wells meets the criterion of "novelty."

The figure shows a schematic diagram of the inventive device.

The structure of the device includes an inlet pipe (1), a separator (2) equipped with a float (3) connected by a rod (4) to a valve (6) mounted on a gas pipeline (5). A high-limit gas meter (7) and a two-position pneumatically controlled valve (11) with position locks (not shown) and a membrane chamber are mounted on the same pipeline.

Moreover, the positive cavity of this chamber using a pulse tube (8) is connected to the cavity of the gas pipeline in the area between the valve and the valve, and the negative chamber cavity, using the pulse tube (14), is connected to the gas riser (15) on the outlet pipe (17) ), which is also part of the device.

A high-limit liquid meter (10) and the same valve (13) are mounted on the liquid pipeline (9), but the positive cavity of its chamber, using the impulse tube (12), is connected to the upper cavity of the separator, and the negative chamber, using the impulse tube ( 16), connected to the same gas riser (15).

The operation of the claimed device is as follows.

In the initial position, the separator (2) is empty, the float (3) lies on the bottom, the shutter (6) is open, the valves (11) and (13) are closed.

The gas-liquid mixture through the inlet pipe (1) enters the upper cavity of the separator and is divided into gas and liquid.

Gas fills the separator. In the separator, the differential pressure rises relative to the outlet pipe (17).

The liquid on the shelves of the separator (not shown in the figure) flows down and accumulates in its lower cavity, its level rises, the float floats up and begins to cover the shutter.

During liquid filling, while the valve is open, if the pressure drop in the separator reaches the upper threshold (for example, 0.7 kgf / cm ² ) of the valve (11), it is sharply set to the “open” position and the gas starts to flow through the meter (7) flow intensively into the outlet pipe (17), the pressure drop decreases.

When the pressure drop of the lower threshold (for example, 0.2 kgf / cm ² ) of the valve (11) is reached, it is sharply set to the “closed” position and the gas flow from the separator to the outlet pipeline stops.

Note - if the gas production rate (under operating conditions) is greater than the liquid production rate, then there can be several such pulses of gas discharge from the separator during the liquid filling cycle.

If the gas flow rate is extremely small, then during a single cycle of liquid filling, not a single cycle of gas discharge from the separator may occur (gas accumulation will continue).

Further, in the process of filling, when the liquid level in the separator reaches a predetermined value (adjustable by rod length 4), the shutter closes.

In this case, the access of gas to the positive cavity of the valve chamber (11) ceases and it (if at that moment was open) is closed.

After closing the damper, gas and liquid continue to flow into the separator. The fluid level continues to rise. The pressure drop due to the compression of the gas "cap" and due to the newly incoming gas also increases.

When the pressure drop of the upper actuation threshold (for example, 1.2 kgf / cm ² ) of the valve (13) is reached, it is sharply set to the “open” position and the liquid through the meter (10) begins to be intensively pushed out by the compressed gas into the outlet pipe (17), the liquid level decreases, the float lowers, trying to open the damper.

At the moment of opening the damper, gas begins to flow into the positive cavity of the valve chamber (11) again, it opens, gas begins to flow into the outlet pipe, and the pressure drop decreases sharply.

When the differential pressure of the lower threshold (for example, 0.7 kgf / cm ² ) is reached, the valve (13) closes and the flow of liquid from the separator to the outlet pipe stops.

The process is then repeated.

The verification of the proposed technical solutions was carried out at the factory metrological stand, which includes calibration and verification measuring modules.

On the calibration module for measuring gas flow, a low limit meter was used with a measurement range from 50 to 2500 m ³ / day (under normal conditions). For measurements of fluid flow, a low-limit meter was used with a measurement range from 24 to 120 t / day.

The module to be verified was equipped in accordance with the circuit diagram shown in the figure.

The valve on the gas pipeline was set to a response range from 0.7 to 0.2 kgf / cm ² , the valve on the liquid pipeline to a range from 1.2 to 0.7 kgf / cm ² .

For gas flow measurements, a high-limit meter was used with a measurement range from 1500 to 75000 m ³ / day.

For measurements of fluid flow, a high-limit meter was used with a measurement range from 144 to 720 t / day.

The essence of the tests was to determine the possibility of measurements using the inventive device equipped with high-limit meters, gas and liquid flow rates, the flow rate of which is less than the lower limit of their flow measurement ranges.

At the same time, the condition was chosen as a criterion for the satisfactory results of the tests: the measurement error should comply with the requirements of GOST R 8.615-2005 “Measuring the amount of oil and gas extracted from the bowels. General metrological and technical requirements. "

During the tests, the gas production rates of 50, 500 and 1000 m ³ / day and the liquid production rates of 25, 50 and 100 tons / day were simulated (set on a calibration module).

At the same time, the largest error in measuring the gas flow was ± 2.8%, and the largest error in measuring the gas flow was ± 1.3%.

Thus, based on the accepted criterion, the test results should be considered satisfactory, since in accordance with GOST R 8.615-2005, the error in measuring gas flow should not be more than ± 5%, liquid ± ± 2.5%.

Information sources

1. USSR author's certificate No. 577290, cl. ЕВВ 43/00, 1975.

2. Copyright certificate SU No. 1530765 A1, cl. ЕВВ 47/10, 1987.

Claims (1)

A device for measuring the flow rate of oil and gas production wells, containing an inlet pipeline, a gas-liquid separator (separator) with a float mechanically connected to the valve, a pipeline, exhaust gas from the separator (gas pipeline) on which this valve is installed, as well as a high-limit gas meter and a two-position pneumatically controlled valve (valve) equipped with position locks ("open" - "closed") and a membrane chamber (chamber), a pipeline that discharges liquid from the separator (liquid pipeline), equipped with a high-limit liquid meter and the same valve, and an outlet pipeline, with the supmembrane (minus) cavities of the chambers of both valves pneumatically connected to the gas riser in the outlet pipeline, and the submembrane (plus) cavity of the valve chamber on the liquid pipeline pneumatically connected to the upper cavity separator, characterized in that the positive cavity of the valve chamber on the gas pipeline is pneumatically connected to the same pipeline - with its cavity between the valve and the valve, and fi the valve position actuators are configured in such a way that the differential pressure values at which the valve in the gas pipeline opens and closes are less than the corresponding differential pressure values at which the valve in the liquid pipeline opens and closes.

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