A gas lift distribution device

By designing a gas lift distribution device, the problem of gas supply from multiple wellheads was solved, achieving efficient and stable gas distribution and improving the production efficiency and recovery rate of oil and gas wells.

CN224338963UActive Publication Date: 2026-06-09CHONGQING OPRO ENERGY TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
CHONGQING OPRO ENERGY TECH CO LTD
Filing Date
2025-05-28
Publication Date
2026-06-09

AI Technical Summary

Technical Problem

In existing technologies, a gas lift device can only supply one wellhead, which cannot meet the needs of multiple wellheads, resulting in low efficiency in oil and gas field development.

Method used

Design a gas lift distribution device, including a main pipeline, branch pipelines, a flow metering device, and a control actuator. The main pipeline distributes high-pressure gas to multiple wellheads, and the flow metering device measures the flow rate in real time. The control actuator automatically adjusts the valve opening to achieve precise control.

Benefits of technology

It enables precise distribution of high-pressure gas to multiple wellheads, ensuring stable and constant gas injection volume, and improving the production efficiency and recovery rate of oil or gas wells.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to oilfield exploitation technical field especially relates to a gas lift distribution device. The utility model embodiment provides a gas lift distribution device, include: main pipeline is connected with compressor for distributing high pressure gas to a plurality of branch pipeline with main pipeline connection;Branch pipeline is used for conveying high pressure gas that main pipeline flows into to oil well or gas well;Flow metering device is used for real -time acquisition flow on branch pipeline;Control executor is used for adjusting the opening of the regulating valve on branch pipeline. The utility model embodiment provides a gas lift distribution device, can distribute high pressure gas provided by a compressor to a plurality of wellheads.
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Description

Technical Field

[0001] This utility model relates to the field of oilfield development technology, and in particular to a gas lift distribution device. Background Technology

[0002] Gas lift distribution equipment is a key device used in the oil and gas field development process. It can accurately distribute high-pressure gas, which has been pressurized, to each oil well or gas well according to a preset distribution plan, so as to achieve efficient and stable oil well or gas well production.

[0003] In related technologies, a gas lift device can only supply one wellhead through a pipeline. If an oil well or gas well has multiple wellheads, multiple gas lift devices are needed to supply multiple wellheads. Utility Model Content

[0004] This utility model provides a gas lift distribution device that can distribute high-pressure gas provided by a compressor to multiple wellheads.

[0005] This utility model embodiment provides an air-lift distribution device, including:

[0006] The main pipeline, connected to the compressor, is used to distribute high-pressure gas to multiple branch pipelines connected to the main pipeline;

[0007] Branch pipelines are used to transport high-pressure gas flowing into the main pipeline to oil wells or gas wells;

[0008] A flow metering device is used to collect the flow rate on the branch pipe in real time;

[0009] A control actuator is used to adjust the opening degree of the regulating valve on the branch pipe.

[0010] One possible design also includes:

[0011] A temperature and pressure acquisition unit is installed at the end of the regulating valve near the main pipeline;

[0012] The temperature and pressure acquisition unit is used to acquire the temperature and pressure of the high-pressure gas to be passed through the regulating valve in real time, and to generate temperature and pressure data.

[0013] The control actuator is used to receive the temperature and pressure data.

[0014] In one possible design, the temperature and pressure acquisition unit is an integrated temperature and pressure transmitter.

[0015] In one possible design, the flow metering device and the temperature and pressure acquisition unit are equipped with a combination of needle valve and three valve groups or a combination of shut-off valve and three valve groups.

[0016] In one possible design, the flow metering device includes an integrated flow meter, which includes a high-pressure pipeline, an internal orifice plate, a gasket, a pipe plug, a temperature transmitter, a pressure tap, a shut-off valve, a three-valve manifold, and a multi-parameter transmitter.

[0017] The high-pressure pipeline is connected to the pipeline whose flow rate is to be measured. An internal orifice plate is installed inside the high-pressure pipeline. The internal orifice plate is a plate body perpendicular to the axis of the high-pressure pipeline, and one or more through holes are opened on the plate body. Pressure tapping pipes are respectively provided on both sides of the internal orifice plate, which pass through and communicate with the high-pressure pipeline. The two pressure tapping pipes are connected to the multi-parameter transmitter through the three sets of valves. The multi-parameter transmitter is used to collect the pressure on both sides of the internal orifice plate through the pressure tapping pipes and calculate the pressure difference. A shut-off valve is installed on the pressure tapping pipe. One end of the high-pressure pipeline is provided with the pipe plug and the sealing gasket. One end of the temperature transmitter passes through the high-pressure pipeline, and the other end is connected to the multi-parameter transmitter.

[0018] In one possible design, both the main pipe and the branch pipe are equipped with ball valves.

[0019] In one possible design, both the main pipe and the branch pipe are mounted on a skid.

[0020] In one possible design, the main pipe of the air lift distribution device is also connected in series with the main pipes or branch pipes of other air lift distribution devices.

[0021] Compared with the prior art, the present invention has at least the following advantages:

[0022] High-pressure gas from the compressor or other equipment first enters the gas lift main pipeline. Then, according to the production needs of each oil and gas well, a preset gas distribution scheme is set for each branch pipeline. Preset flow rates can be remotely set, and the gas is distributed to the corresponding oil and gas wells through the branch pipelines. During the distribution process, the gas lift flow metering device measures the gas flow rate in real time, obtaining flow data, and transmits this data to the control actuator. Based on the collected flow data, the control actuator automatically adjusts the opening of the control valve to achieve precise control of the gas injection volume of each individual well. This ensures that the gas injection volume remains stable and constant even when the injection pressure of a single well changes, thereby improving the production efficiency and recovery rate of the oil or gas well. Furthermore, this application also allows adjustment of the control valve opening via the touchscreen of the control actuator. It should also be noted that the control valve opening can also be adjusted using a specific wrench. Attached Figure Description

[0023] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0024] Figure 1 This is a schematic diagram of the structure of an air-lift distribution device provided in an embodiment of this utility model;

[0025] Figure 2 This is a schematic diagram of another air-lift distribution device provided in this embodiment of the present invention;

[0026] Figure 3 This is a schematic diagram of the structure of an integrated flow meter provided in an embodiment of this utility model;

[0027] Figure 4 This is a schematic diagram of another integrated flow meter provided in this embodiment of the utility model.

[0028] In the picture:

[0029] 1-Main pipeline;

[0030] 2-branch pipes;

[0031] 3-Control actuator;

[0032] 4-Regulating valve;

[0033] 5-Integrated flow meter;

[0034] 51-High-pressure pipeline;

[0035] 52- Built-in perforated plate;

[0036] 53 - Sealing gasket;

[0037] 54 - Pipe plug;

[0038] 55 - Temperature transmitter;

[0039] 56 - Pressure tapping tube;

[0040] 57 - Shut-off valve;

[0041] 58 - Three sets of valves;

[0042] 59 - Multi-parameter transmitter;

[0043] 6-Lever mount. Detailed Implementation

[0044] To make the objectives, technical solutions, and advantages of the embodiments of this utility model clearer, the technical solutions of the embodiments of this utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of this utility model, not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of this utility model without creative effort are within the scope of protection of this utility model.

[0045] In the description of the embodiments of this utility model, unless otherwise expressly specified and limited, the terms "first" and "second" are used for descriptive purposes only and should not be construed as indicating or implying relative importance; unless otherwise specified or explained, the term "multiple" refers to two or more; the terms "connected," "fixed," etc., should be interpreted broadly. For example, "connected" can be a fixed connection, a detachable connection, an integral connection, or an electrical connection; it can be a direct connection or an indirect connection through an intermediate medium. Those skilled in the art can understand the specific meaning of the above terms in this utility model according to the specific circumstances.

[0046] In this specification, it should be understood that the directional terms such as "upper" and "lower" used in the description of the embodiments of this utility model are used to describe the angles shown in the accompanying drawings and should not be construed as limiting the embodiments of this utility model. Furthermore, in the context, it should also be understood that when it is mentioned that one element is connected "upper" or "lower" to another element, it can be directly connected to the other element "upper" or "lower," or indirectly connected to the other element "upper" or "lower" through an intermediate element.

[0047] like Figure 1 As shown, this embodiment of the present invention provides an air-lift distribution device, comprising:

[0048] Main pipe 1, connected to the compressor, is used to distribute high-pressure gas to multiple branch pipes connected to the main pipe;

[0049] Branch pipe 2 is used to transport the high-pressure gas flowing into it from the main pipe to the oil well or gas well;

[0050] Flow metering device, used to collect flow rate on branch pipes in real time;

[0051] The control actuator 3 is used to adjust the opening degree of the regulating valve 4 on the branch pipeline.

[0052] In this invention, high-pressure gas from a compressor or other equipment first enters the gas lift main pipeline 1. Then, according to the production needs of each oil and gas well, a preset gas distribution scheme is set for each branch pipeline 2. The preset flow rate value can be remotely set, and the gas is distributed to the corresponding oil and gas wells through the branch pipelines 2. During the distribution process, the gas lift flow metering device measures the gas flow rate in real time, obtains flow data, and transmits this data to the control actuator 3. The control actuator automatically adjusts the opening of the control valve based on the collected flow data to achieve precise control of the gas injection volume of each individual well, ensuring that the gas injection volume remains stable and constant when the gas injection pressure of a single well changes, thereby improving the production efficiency and recovery rate of the oil or gas well. In addition, this application also allows manual adjustment of the opening of the regulating valve via the touch screen of the control actuator. It should also be noted that the opening of the regulating valve can also be adjusted using a specific wrench.

[0053] The present invention provides a wide temperature range, high precision, multi-well intelligent gas lift distribution device, which consists of 1 to 10 sets of ±0.2‰ high precision flow control devices, 1 to 10 sets of large range, multi-parameter differential pressure flow meters, ultra-high conversion efficiency heating system, and modular process pipelines.

[0054] Connection relationship: The flow control device and the differential pressure flow meter are connected in series through the process pipeline to monitor the gas lift in real time; the heating system uses electric heat tracing and coils to compensate for the temperature of the pipeline and valve body, forming a closed-loop control network.

[0055] Core function: Achieve a torque range of -50 to 5000 Nm 3 Stepless automatic allocation of gas lift from multiple wells within a range of / h (single well allocation accuracy ±1Nm) 3 / h), supporting continuous gas lift operations around the clock for shale gas, tight gas, and coalbed methane wells in high-altitude and cold regions.

[0056] High-precision gas lift distribution technology: The independently developed ±0.2‰ precision actuator breaks through the problems of large flow fluctuation and slow response of traditional gas lift equipment, and reduces ineffective gas injection by 30% in the Changqing Gas Field test.

[0057] In some embodiments of this utility model, a temperature and pressure acquisition unit is provided at the end of the regulating valve near the main pipeline 1;

[0058] The temperature and pressure acquisition unit is used to acquire the temperature and pressure of the high-pressure gas to be passed through the regulating valve 4 in real time, and generate temperature and pressure data.

[0059] The control actuator is used to receive temperature and pressure data.

[0060] In this embodiment, the data collected by the temperature and pressure acquisition unit is transmitted to the control actuator 3. The control actuator 3 stores a preset safety range. The control actuator 3 determines whether the received temperature and pressure data is within the safety range. If it is, it indicates that the current situation is relatively safe. If it is not, there is a risk. The control actuator 3 will then issue an alarm or close the regulating valve 4 for maintenance.

[0061] In addition, after receiving the temperature and pressure data, the control actuator 3 can also calculate the flow rate in the branch pipe 2 based on the temperature and pressure data and the pressure difference of the differential pressure gauge.

[0062] In some embodiments of this utility model, the temperature and pressure acquisition unit is an integrated temperature and pressure transmitter.

[0063] In some embodiments of this utility model, the flow metering device and the temperature and pressure acquisition unit are equipped with a combination of needle valve and three valve groups or a combination of shut-off valve and three valve groups.

[0064] In this embodiment, the combination of needle valve and three valve groups or the combination of shut-off valve and three valve groups is used to switch on and off each gas detection module. When repairing or replacing the detection unit, maintenance can be carried out without interrupting production.

[0065] Please refer to Figure 3 and Figure 4 In some embodiments of this utility model, the flow metering device includes an integrated flow meter 5, which includes a high-pressure pipeline 51, an internal orifice plate 52, a sealing gasket 53, a pipe plug 54, a temperature transmitter 55, a pressure tapping pipe 56, a shut-off valve 57, a three-valve manifold, and a multi-parameter transmitter 59.

[0066] The high-pressure pipeline 51 is connected to the pipeline whose flow rate is to be measured. An internal orifice plate 52 is installed inside the high-pressure pipeline 51. The internal orifice plate 52 is a plate body perpendicular to the axis of the high-pressure pipeline 51. One or more through holes are opened on the plate body. Pressure tapping pipes 56 are respectively provided on both sides of the internal orifice plate 52, which pass through and communicate with the high-pressure pipeline 51. The two pressure tapping pipes 56 are connected to the multi-parameter transmitter 59 through three sets of valves 58. The multi-parameter transmitter 59 is used to collect the pressure on both sides of the internal orifice plate 52 through the pressure tapping pipes 56 and calculate the pressure difference. A shut-off valve 57 is installed on the pressure tapping pipes 56. A pipe plug 54 and a sealing gasket 53 are provided at one end of the high-pressure pipeline 51. One end of the temperature transmitter 55 passes through the high-pressure pipeline 51, and the other end is connected to the multi-parameter transmitter 59.

[0067] In this embodiment, the standard orifice plate of the orifice plate flow meter 5 is installed between the orifice plate flanges. When the fluid flows through the standard orifice plate, a pressure difference will be generated between its upstream and downstream sides. The flow rate through the orifice plate can be calculated according to Bernoulli's equation (or other equations).

[0068] In some embodiments of this utility model, both the main pipeline 1 and the branch pipeline 2 are equipped with ball valves. The ball valves allow for manual closure of both the main pipeline 1 and the branch pipeline 2 (the ball valve on the main pipeline 1 is used to switch on / off the next air lift skid (the next air lift skid can be branch 1, branch 2, branch 3, branch 4, or branch 5)). Specifically, a ball valve is installed at the outlet of the main pipeline 1, and the ball valve on the branch pipeline 2 is installed upstream of the regulating valve.

[0069] In some embodiments of this utility model, both the main pipeline 1 and the branch pipeline 2 are installed on the skid base 6. The skid base 6 is a basic support structure that supports other components. It is made of high-strength steel and has sufficient strength and stability to adapt to the harsh environment of the oilfield.

[0070] like Figure 2 As shown, in some embodiments of this utility model, the main pipe 1 is also connected in series with the main pipe 1 or branch pipe 2 of other air lift distribution devices.

[0071] Finally, it should be noted that the above embodiments are only used to illustrate the technical solutions of this utility model, and not to limit it. Although this utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art should understand that modifications can still be made to the technical solutions described in the foregoing embodiments, or equivalent substitutions can be made to some of the technical features. Such modifications or substitutions do not cause the essence of the corresponding technical solutions to deviate from the spirit and scope of the technical solutions of the embodiments of this utility model.

Claims

1. A gas lift distribution device, characterized by, include: The main pipeline, connected to the compressor, is used to distribute high-pressure gas to multiple branch pipelines connected to the main pipeline; Branch pipes are used to transport high-pressure gas flowing into them from the main pipe to oil wells or gas wells; A flow metering device is used to collect the flow rate on the branch pipe in real time; A control actuator is used to adjust the opening degree of the regulating valve on the branch pipe; A temperature and pressure acquisition unit is installed at the end of the regulating valve near the main pipeline; The temperature and pressure acquisition unit is used to acquire the temperature and pressure of the high-pressure gas to be passed through the regulating valve in real time, and to generate temperature and pressure data. The control actuator is used to receive the temperature and pressure data; The temperature and pressure acquisition unit is an integrated temperature and pressure transmitter; The flow metering device and the temperature and pressure acquisition unit are equipped with a combination of needle valve and three valve groups or a combination of shut-off valve and three valve groups. The flow metering device includes an integrated flow meter, which includes a high-pressure pipeline, an internal orifice plate, a sealing gasket, a pipe plug, a temperature transmitter, a pressure tapping pipe, a shut-off valve, a three-valve manifold, and a multi-parameter transmitter. The high-pressure pipeline is connected to the pipeline whose flow rate is to be measured. The high-pressure pipeline has an internal orifice plate installed inside. The internal orifice plate is a plate body perpendicular to the axis of the high-pressure pipeline. One or more through holes are opened on the plate body. Pressure tapping pipes are respectively provided on both sides of the internal orifice plate, which pass through and communicate with the high-pressure pipeline. The two pressure tapping pipes are connected to the multi-parameter transmitter through the three sets of valves. The multi-parameter transmitter is used to collect the pressure on both sides of the internal orifice plate through the pressure tapping pipes and calculate the pressure difference. A shut-off valve is installed on the pressure tapping pipe. One end of the high-pressure pipeline is provided with the pipe plug and the sealing gasket. One end of the temperature transmitter passes through the high-pressure pipeline, and the other end is connected to the multi-parameter transmitter. Both the main pipeline and the branch pipeline are equipped with ball valves; Both the main pipeline and the branch pipeline are installed on the skid mount; The main pipe of the gas lift distribution device is also connected in series with the main pipes or branch pipes of other gas lift distribution devices.