CN214333964U - Online self-calibration oil-gas-water three-phase metering device - Google Patents

Abstract

The utility model discloses an on-line self-calibration oil-gas-water three-phase metering device, which comprises a multiphase flow mixer, a separation pipe and a flow computer, one end of the multiphase flow mixer is provided with an oil-gas-water inlet pipe which is communicated with the position of the separation pipe close to the top, one end of the multiphase flow mixer far away from the oil-gas-water inlet pipe is provided with an oil-gas-water inlet communicated with the inside of the multiphase flow mixer, the top of the separation pipe is provided with a gas phase pipeline communicated with the inside of the separation pipe, the bottom of the separation pipe is provided with an outlet pipeline communicated with the inside of the separation pipe, the gas phase pipeline is communicated with one end of the outlet pipeline far away from the separation pipe, an oil-gas-water outlet is arranged at the communication position of the gas phase pipeline and the outlet pipeline, the gas phase pipeline is provided with a gas-liquid two-phase flowmeter, and the outlet pipeline is sequentially provided with an electric three-way valve and a gas-liquid two-phase mass flowmeter from one end close to the separation pipe to one end far away from the separation pipe. The utility model discloses can compromise gas-liquid two-phase flow measurement and oily water measurement dual mode simultaneously, the measurement mode is simple, high-efficient and accurate.

Description

Online self-calibration oil-gas-water three-phase metering device

Technical Field

The utility model belongs to heterogeneous flow measurement field, concretely relates to online self calibration oil gas water three-phase metering device.

Background

At present, the large separator is mostly adopted for measuring the single-well multiphase flow of the oil field well mouth in China, and for some high-yield oil and gas wells or high-yield oil and gas wells which are produced quickly in the early high-yield later period, a user also has to design the large separator, especially when the large separator meets high-pressure and highly corrosive medium fluid, the measuring equipment is large, special materials are needed, the cost is high, and the user and the designer are very involved. The factors of dirt content, high wax content, high water mineralization degree and the like in the wellhead fluid cause that the oil-water content measuring instrument needs to be maintained and cleaned frequently, and the production cost is increased. The metering device is introduced with a density method and automatic heating wax-dissolving, so that oil-gas-water three-phase flow metering with reliable performance is formed.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that just not enough to above-mentioned prior art provides an online self calibration oil gas water three-phase metering device, can compromise gas-liquid two-phase flow measurement and oily water measurement dual mode simultaneously, and the measurement mode is simple, high-efficient and accurate.

The utility model adopts the technical proposal that: the utility model provides an online self calibration oil gas water three-phase metering device, includes heterogeneous flow mixer, separator tube and flow computer, heterogeneous flow mixer side is equipped with the level gauge through the connecting pipe, heterogeneous flow mixer wherein one end be equipped with the separator tube near the oil gas water inlet pipe of top position intercommunication, heterogeneous flow mixer keeps away from the one end that oil gas water inlet pipe is equipped with rather than inside intercommunication's oil gas water entry, the separator tube top is equipped with rather than inside intercommunication's gaseous phase pipeline, the separator tube bottom is equipped with rather than inside intercommunication's outlet pipeline, gaseous phase pipeline and outlet pipeline keep away from the one end intercommunication of separator tube, gaseous phase pipeline and outlet pipeline intercommunication department are equipped with oil gas water export, be equipped with gas-liquid two-phase flowmeter and manual regulation valve in proper order from the one end that is close to the separator tube to the one end of keeping away from the separator tube on the gaseous phase pipeline, be equipped with electric three-way valve in proper order from the one end that is close to the separator tube to the one end of keeping away from the separator tube on the outlet pipeline, The oil-gas-water dual-phase mass flowmeter comprises an oil-gas-water dual-phase mass flowmeter and an electric adjusting switch valve, wherein an oil-water content measuring sampling pipe communicated with an electric three-way valve is arranged on an oil-gas-water inlet pipe, an exhaust pipe is arranged between a gas-phase pipeline and an outlet pipeline, two ends of the exhaust pipe are respectively communicated with the gas-phase pipeline and the outlet pipeline, an oil-gas-water inlet, a multiphase flow mixer, a separating pipe, the gas-phase pipeline, the oil-gas-water dual-phase flowmeter, a manual adjusting valve, the electric three-way valve, the gas-liquid dual-phase mass flowmeter, the liquid level meter, an interface switch valve, the oil-water content measuring sampling pipe, the outlet pipeline, the exhaust pipe, an oil-gas-water outlet, an oil-gas-water inlet pipe and a connecting pipe are all wound with electric tracing bands, and the gas-liquid dual-phase flowmeter, the electric three-gas-liquid dual-phase mass flowmeter, the electric adjusting switch valve and the electric tracing bands are all electrically connected with a flowmeter computer.

In one embodiment, the two connecting pipes are respectively communicated with the positions of the separating pipe near the top and near the bottom.

In one embodiment, two connecting pipes are provided with interface switch valves.

The beneficial effects of the utility model reside in that:

1. the device can simultaneously take two modes of gas-liquid two-phase flow metering and oil-water content metering into consideration, and can simultaneously meet the requirements of large flow separation metering and small flow separation metering under the gas-liquid two-phase flow metering state, and the metering mode is simple, efficient and accurate;

2. through the arrangement of the electric tracing band, the effects of viscosity reduction, wax melting and bubble removal can be realized through heating during oil water content measurement, and the accuracy of final measurement is ensured.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

In the figure: 1. an oil-gas-water inlet; 2. a multiphase flow mixer; 3. a separation tube; 4. a gas phase line; 5. a gas-liquid two-phase flow meter; 6. a manual regulating valve; 7. an electric three-way valve; 8. a gas-liquid two-phase mass flowmeter; 9. an electrically-operated regulating switch valve; 10. a liquid level meter; 11. an interface switching valve; 12. an oil water content measurement sampling tube; 13. an outlet line; 14. an exhaust pipe; 15. an oil-gas-water outlet; 16. a flow computer; 17. oil gas water inlet pipe; 18. and (4) connecting the pipes.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments.

As shown in fig. 1, an on-line self-calibration oil-gas-water three-phase metering device comprises a multiphase flow mixer 2, a separation pipe 3 and a flow computer 16, wherein a liquid level meter 10 is arranged on the side surface of the multiphase flow mixer 2 through a connecting pipe 18, an oil-gas-water inlet pipe 17 communicated with the separation pipe 3 close to the top is arranged at one end of the multiphase flow mixer 2 far away from the oil-gas-water inlet pipe 17, an oil-gas-water inlet 1 communicated with the inside of the multiphase flow mixer is arranged at one end of the multiphase flow mixer 2 far away from the oil-gas-water inlet pipe 17, an oil-gas-water outlet 4 communicated with the inside of the separation pipe 3 is arranged at the top of the separation pipe 3, an outlet pipeline 13 communicated with the inside of the separation pipe 3 is arranged at the bottom of the separation pipe 3, the oil-gas pipeline 4 is communicated with one end of the separation pipe 3 far away from the gas-water outlet pipeline 4, a gas-gas two-phase flow meter 5 and a manual regulating valve 6 are sequentially arranged on the oil-gas pipeline 4 from one end close to one end of the separation pipe 3, an electric three-way valve 7, a gas-liquid two-phase mass flow meter 8 and an electric adjusting switch valve 9 are sequentially arranged on the outlet pipeline 13 from one end close to the separation pipe 3 to one end far away from the separation pipe 3, an oil-gas-water measuring sampling pipe 12 communicated with the electric three-way valve 7 is arranged on the oil-gas-water inlet pipe 17, an exhaust pipe 14 with two ends respectively communicated with the gas-phase pipeline 4 and the outlet pipeline 13 is arranged between the gas-phase pipeline 4 and the outlet pipeline 13, an oil-gas-water inlet 1, a multiphase flow mixer 2, the separation pipe 3, the gas-phase pipeline 4, the gas-liquid two-phase flow meter 5, a manual adjusting valve 6, the electric three-way valve 7, the gas-liquid two-phase mass flow meter 8, the electric adjusting switch valve 9, a liquid level meter 10, an interface switch valve 11, the oil-water measuring sampling pipe 12, the outlet pipeline 13, the exhaust pipe 14, an oil-gas-water outlet 15, the oil-gas-water inlet pipe 17 and a connecting pipe 18 are all wound with electric tracing bands, the gas-liquid two-phase flowmeter 5, the electric three-way valve 7, the gas-liquid two-phase mass flowmeter 8, the electric regulating switch valve 9 and the electric tracing band are all electrically connected with a flow computer 16.

In this embodiment, the two connecting pipes 18 are respectively communicated with the positions near the top and the bottom of the separating pipe 3.

In this embodiment, the two connection pipes 18 are provided with the interface switch valves 11.

Utilize an online self calibration oil gas water three-phase metering device can carry out oil gas water three-phase measurement, it includes following step:

step 10, an oil-gas-water mixture enters a multiphase flow mixer 2 from an oil-gas-water inlet 1, and enters step 20 if gas-liquid two-phase flow metering is carried out, and enters step 90 if oil-water content metering is carried out;

step 20, if the large flow separation metering is carried out, entering step 30, and if the small flow separation metering is carried out, entering step 60;

step 30, the flow computer 16 controls the electric three-way valve 7 to conduct the outlet pipeline 13 and close the oil-water content measurement sampling pipe 12, meanwhile, the flow computer 16 controls the electric adjusting switch valve 9 to be opened and switches the electric adjusting switch valve 9 to a manual operation state, and the step 40 is entered;

step 40, enabling the oil-gas mixture to enter a separation pipe 3 through an oil-gas-water inlet pipe 17, separating the oil-gas-water mixture through the separation pipe 3, manually adjusting a manual adjusting valve 6 and an electric adjusting switch valve 9 according to display data of a liquid level meter 10 to ensure that a gas phase exists in a gas phase pipeline 4 and simultaneously ensuring that an outlet pipeline 13 is in a gas-liquid two-phase state, and entering step 50;

step 50, the gas-liquid two-phase flowmeter 5 measures the gas-phase flow passing through the gas-phase pipeline 4, the gas-liquid two-phase mass flowmeter 8 measures the gas-liquid two-phase flow passing through the outlet pipeline 13, the flow computer 16 displays the total liquid-phase flow and the total gas-phase flow in real time, if the device runs normally, the electric regulating switch valve 9 is switched to an automatic working state, and the large-flow separation measurement is finished;

step 60, the flow computer 16 controls the electric three-way valve 7 to conduct the outlet pipeline 13 and close the oil-water content measurement sampling pipe 12, and meanwhile, the flow computer 16 controls the electric adjusting switch valve 9 to be opened, and the step 70 is carried out;

step 70, setting a liquid level high-low value of the liquid level meter 10 by the flow computer 16, controlling the electric regulating switch valve 9 to perform position type control metering according to the set liquid level high-low value, and entering step 80;

80, the oil-gas mixture enters a separation pipe 3 through an oil-gas-water inlet pipe 17, the separation pipe 3 separates the oil-gas mixture, a separated gas phase is measured through a gas-liquid two-phase flowmeter 5, a separated liquid phase is measured through a gas-liquid two-phase mass flowmeter 8, a flow computer 16 displays total liquid phase flow and total gas phase flow in real time, and the small-flow separation measurement is finished;

step 90, setting oil water content measurement time and oil water content measurement interval time, controlling an electric three-way valve 7 by a flow computer 16 to close an outlet pipeline 13 and conduct an oil water content measurement sampling pipe 12, controlling an electric adjusting switch valve 9 to open by the flow computer 16, enabling an oil-gas-water mixture to enter the outlet pipeline 13, if the oil water content measurement interval time is not reached, enabling the oil-gas-water mixture to sequentially pass through the oil water content measurement sampling pipe 12, the electric three-way valve 7 and the outlet pipeline 13 and be discharged from an oil-gas-water outlet 15, and if the oil water content measurement interval time is reached, entering step 100;

step 100, the flow computer 16 controls the electric regulating switch valve 9 to be closed, the oil-gas-water mixture stops flowing, gas in the outlet pipeline 13 enters the gas phase pipeline 4 through the exhaust pipe 14 and is discharged from the oil-gas-water outlet 15, the flow computer 16 controls the electric tracing band to work, when the oil water content measuring time is up, the flow computer 16 reads the density of the oil-water mixture measured by the gas-liquid two-phase mass flowmeter 8 and calculates the oil water content percentage, and the step 110 is carried out;

and step 110, the flow computer 16 controls the electric three-way valve 7 to conduct the outlet pipeline 13 and close the oil and water content measurement sampling pipe 12, and meanwhile, the flow computer 16 controls the electric adjusting switch valve 9 to be opened, so that the oil and water content measurement is finished.

In the above metering method, the gas-liquid two-phase flow metering further comprises a self-calibration step, specifically as follows:

the manual regulating valve 6 and the electric regulating switch valve 9 are manually regulated according to the display data of the liquid level meter 10, the liquid level is controlled to the middle position of the liquid level meter 10, the gas-liquid two-phase flow meter 5 meters the gas phase flow passing through the gas phase pipeline 4, the gas-liquid two-phase mass flow meter 8 meters the gas-liquid two-phase flow passing through the outlet pipeline 13, and the flow computer 16 displays the total liquid phase flow and the total gas phase flow in real time.

In the above-mentioned metering method, in step 70, the electric regulating switch valve 9 is controlled to perform position-type control metering according to the set liquid level height value, specifically as follows:

the electric adjustment switch valve 9 is opened when the liquid level reaches a set high level value, and the electric adjustment switch valve 9 is closed when the liquid level reaches a set low level value.

In the above-mentioned measuring method, in step 100, when the flow computer 16 calculates the oil water content percentage, the oil water content percentage is calculated by the crude oil density and the water density set by the flow computer 16 and the compensation formula of the crude oil density and the water density changing with the temperature.

In the above metering method, the set crude oil density and water density are average values of the crude oil density and water density measured before the current measurement.

The gas-liquid two-phase mass flowmeter 8 of the device and the electric tracing band wound at the front section and the rear section of the outlet pipeline 13 are more dense than other parts of the device. The electric tracing band can be replaced by other electric heaters.

The large flow and the small flow in the gas-liquid two-phase flow metering in the device are set and distinguished according to the flow capacity and the metering range of each part of the device. At a large flow, the device cannot completely separate oil-gas-water mixtures, so that the manual regulating valve 6 and the electric regulating switch valve 9 need to be manually regulated according to display data of the liquid level meter 10. And after the device runs normally, switching the electric regulating switch valve 9 to an automatic working state. And, when the small flow, the device can carry out the complete separation to oil gas water mixture, consequently can adjust the device to automatic operating condition. In the metering method, the oil water content measurement interval time is the time for replacing the fluid medium, and the time can be set according to the actual situation.

The device part of the utility model can simultaneously take into account two modes of gas-liquid two-phase flow measurement and oil-water content measurement, and also can simultaneously meet the large flow separation measurement and the small flow separation measurement under the gas-liquid two-phase flow measurement state, and the measurement mode is simple, efficient and accurate; through the arrangement of the electric tracing band, the effects of viscosity reduction, wax melting and bubble removal can be realized through heating during oil water content measurement, and the accuracy of final measurement is ensured.

The above-mentioned embodiments only express the specific embodiments of the present invention, and the description thereof is specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention.

Claims (3)

1. An on-line self-calibration oil-gas-water three-phase metering device is characterized by comprising a multi-phase flow mixer, a separating pipe and a flow computer, wherein a liquid level meter is arranged on the side surface of the multi-phase flow mixer through a connecting pipe, an oil-gas-water inlet pipe communicated with the separating pipe close to the top is arranged at one end of the multi-phase flow mixer far away from the oil-gas-water inlet pipe, an oil-gas-water inlet communicated with the inside of the multi-phase flow mixer is arranged at one end of the multi-phase flow mixer far away from the oil-gas-water inlet pipe, a gas-phase pipeline communicated with the inside of the separating pipe is arranged at the top of the separating pipe, an outlet pipeline communicated with the inside of the separating pipe is arranged at the bottom of the separating pipe, the gas-phase pipeline and one end of the outlet pipeline far away from the separating pipe are communicated, an oil-gas-water outlet is arranged at the communication position of the gas-phase pipeline and the outlet pipeline, a gas-liquid two-phase flow meter and a manual regulating valve are sequentially arranged on the gas-phase pipeline from one end close to one end far away from the separating pipe, the device is characterized in that an electric three-way valve, a gas-liquid two-phase mass flowmeter and an electric adjusting switch valve are sequentially arranged on the outlet pipeline from one end close to the separation pipe to one end far away from the separation pipe, an oil-water content measuring sampling pipe communicated with the electric three-way valve is arranged on the oil-gas-water inlet pipe, an exhaust pipe is arranged between the gas-gas pipeline and the outlet pipeline, the two ends of the exhaust pipe are respectively communicated with the gas-gas pipeline and the outlet pipeline, an oil-gas-water inlet, a multiphase flow mixer, the separation pipe, the gas-phase pipeline, the gas-liquid two-phase flowmeter, a manual adjusting valve, an electric three-way valve, the gas-liquid two-phase mass flowmeter, the electric adjusting switch valve, a liquid level meter, an interface switch valve, the oil-water content measuring sampling pipe, the outlet pipeline, the exhaust pipe, the oil-gas-water outlet, the oil-gas-water inlet pipe and the connecting pipe are all wound with electric tracing bands, and the gas-liquid two-phase flowmeter, the electric three-liquid-gas-liquid-phase mass flowmeter, the electric three-liquid-phase mass flowmeter, the oil-water-gas-water-outlet, the oil-water-gas flowmeter, the separation pipe-gas flowmeter, the electric three-gas-three-gas-three-liquid-three-phase flowmeter, the electric-gas-liquid-three-liquid-phase flowmeter, the electric-liquid-phase mass flowmeter, the electric-liquid-phase flowmeter, the electric-liquid, The electric regulating switch valve and the electric tracing band are electrically connected with the flow computer.

2. The on-line self-calibrating oil-gas-water three-phase metering device as claimed in claim 1, wherein the two connecting pipes are respectively communicated with the positions of the separating pipe close to the top and the bottom.

3. The on-line self-calibration oil-gas-water three-phase metering device as claimed in claim 2, wherein an interface switch valve is arranged on each of the two connecting pipes.

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