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CN-121998786-A - Inspection method, device, equipment and storage medium of oil and gas exploitation system

CN121998786ACN 121998786 ACN121998786 ACN 121998786ACN-121998786-A

Abstract

The application discloses a patrol method, device and equipment for an oil gas exploitation system and a storage medium, and belongs to the technical field of oil gas exploitation. The method comprises the steps of obtaining basic information related to a routing inspection point, wherein the routing inspection point comprises equipment components to be inspected in an oil gas exploitation system, the basic information represents the association relation between the routing inspection point and routing inspection equipment, first routing inspection information is generated by utilizing the basic information and routing inspection tasks of the routing inspection point, conflict detection is conducted on the first routing inspection information, the first routing inspection information is optimized based on the result of the conflict detection to obtain second routing inspection information, routing inspection is conducted on the routing inspection point based on the second routing inspection information to obtain first routing inspection data and second routing inspection data, the first routing inspection data comprises routing inspection images acquired by image acquisition equipment, the second routing inspection data comprises information acquired by equipment sensors, and routing inspection results are generated based on the first routing inspection data and the second routing inspection data. The method can improve the inspection accuracy and the inspection efficiency of the oil gas exploitation equipment in the oil gas exploitation system.

Inventors

  • ZHANG DUNJIAN
  • SHEN JIAHUI
  • FAN JING
  • SUN SHISHENG
  • ZHANG ZHONGJIE
  • ZHANG KAIYUAN
  • TONG FEI
  • LI ZHONGJIAN
  • YONG GUOQIANG
  • XIAO SHAOJIAN

Assignees

  • 昆仑数智科技有限责任公司
  • 中国石油天然气集团有限公司

Dates

Publication Date
20260508
Application Date
20241107

Claims (13)

  1. 1. A method of inspection of an oil and gas production system, the method comprising: acquiring basic information associated with a patrol point, wherein the patrol point comprises equipment components to be patrol in an oil and gas exploitation system, the basic information represents the association relation between the patrol point and patrol equipment, and the patrol equipment comprises image acquisition equipment and equipment sensors; Generating first inspection information by utilizing the basic information and the inspection task of the inspection point; Performing conflict detection on the first inspection information, and optimizing the first inspection information based on a conflict detection result to obtain second inspection information; The inspection points are inspected based on the second inspection information, first inspection data and second inspection data are obtained, the first inspection data comprise inspection images of the inspection points collected by the image collecting equipment, and the second inspection data comprise information of the inspection points collected by the equipment sensor; And generating a patrol result based on the first patrol data and the second patrol data.
  2. 2. The method of claim 1, wherein the first inspection information includes a first inspection path and a first inspection time of the inspection point, wherein generating the first inspection information using the base information and an inspection task of the inspection point comprises: configuring a first inspection time of the inspection point by utilizing an inspection task of the inspection point; And generating the first inspection path based on the first inspection time and the basic information.
  3. 3. The method of claim 2, wherein the result of the collision detection includes a first collision detection result, wherein the performing collision detection on the first inspection information, and wherein optimizing the first inspection information based on the result of the collision detection, to obtain the second inspection information, includes: Performing conflict detection on the first inspection time of the inspection point to obtain a first conflict detection result, wherein the first conflict detection result represents the conflict condition of the first inspection time of the inspection point; And under the condition that the first conflict detection result indicates that conflict patrol points with the same or overlapped first patrol time exist, acquiring patrol equipment associated with the conflict patrol points, and optimizing the patrol equipment associated with the conflict patrol points to obtain the second patrol information.
  4. 4. The method of claim 2, wherein the collision detection result includes a second collision detection result, wherein the performing collision detection on the first inspection information, and optimizing the first inspection information based on the result of collision detection, to obtain the second inspection information, includes: Performing conflict detection on the first inspection path to obtain a second conflict detection result, wherein the second conflict detection result indicates the conflict condition of the first inspection path of the inspection point; And under the condition that the second conflict detection result shows that a conflict inspection point exists based on the first inspection path, acquiring the back-off time of the conflict inspection point, optimizing the inspection sequence of the inspection points based on the back-off time of the conflict inspection point, and obtaining the second inspection information, wherein the back-off time is determined based on the inspection task.
  5. 5. The method of claim 1, wherein the inspecting the inspection point based on the second inspection information to obtain first inspection data comprises: Determining a plurality of first inspection images of the inspection points acquired by the image acquisition equipment within a reference time period based on the second inspection information; Determining first reference elements in the plurality of first inspection images, and calculating element offset of the first reference elements in the plurality of first inspection images, wherein the first reference elements are picture elements contained in the plurality of first inspection images, and the element offset represents the position change quantity of the first reference elements relative to the image acquisition equipment in the reference time period; and determining the first inspection data based on the first inspection image under the condition that the element offset is less than or equal to an offset threshold.
  6. 6. The method of claim 1, wherein the inspecting the inspection point based on the second inspection information to obtain first inspection data comprises: determining a second inspection image of the inspection point acquired by the image acquisition equipment based on the second inspection information; determining a second reference element in the second inspection image, and calculating the edge ambiguity of the second reference element, wherein the second reference element is a picture element contained in the second inspection image, and the edge ambiguity represents the ambiguity of the edge of the second reference element; and determining the first inspection data based on the second inspection image under the condition that the edge ambiguity is less than or equal to an ambiguity threshold.
  7. 7. The method according to any one of claims 1 to 6, further comprising, before the obtaining the basic information associated with the inspection point: Acquiring acquisition areas of the image acquisition equipment and the equipment sensor, and determining identifiers of inspection points included in the acquisition areas; and associating the inspection point with the image acquisition equipment and the equipment sensor based on the identifier of the inspection point to obtain the basic information of the inspection point.
  8. 8. The method of any one of claims 1 to 6, wherein prior to generating the first inspection information using the base information and the inspection task of the inspection point, further comprising: Acquiring control states of the image acquisition equipment and the equipment sensor; the generating the first inspection information by using the basic information and the inspection task of the inspection point includes: and generating the first inspection information by using the basic information, the inspection task of the inspection point and the control state.
  9. 9. The method according to any one of claims 1 to 6, further comprising: Determining data processing parameters of inspection reference data, wherein the inspection reference data represents process data acquired or generated in an inspection process, the inspection reference data comprises at least one of inspection images or inspection point information, and the data processing parameters are used for determining at least one of a processing model, data quantity or processing data occupation calculation force of the inspection reference data; Acquiring the use state of operation resources of a processor in data processing equipment, wherein the data processing equipment comprises a plurality of processors, and the processors are used for processing the patrol reference data; Allocating a corresponding processor for the inspection reference data from the plurality of processors based on the use state of the operation resource and the data processing parameter; and processing the inspection reference data based on the distributed processor to obtain a data processing result, wherein the data processing result comprises at least one of the first inspection information, the second inspection information, the first inspection data, the second inspection data or the inspection result.
  10. 10. An inspection device for an oil and gas production system, the device comprising: The system comprises an acquisition module, a detection module and a detection module, wherein the acquisition module is used for acquiring basic information associated with a detection point, the detection point comprises equipment components to be detected in an oil gas exploitation system, the basic information represents the association relation between the detection point and detection equipment, and the detection equipment comprises image acquisition equipment and an equipment sensor; the generation module is used for generating first inspection information by utilizing the basic information and the inspection task of the inspection point; The optimizing module is used for carrying out conflict detection on the first inspection information, optimizing the first inspection information based on a conflict detection result and obtaining second inspection information; The inspection module is used for inspecting the inspection points based on the second inspection information to obtain first inspection data and second inspection data, wherein the first inspection data comprises inspection images of the inspection points acquired by the image acquisition equipment, and the second inspection data comprises information of the inspection points acquired by the equipment sensor; The inspection module is further used for generating an inspection result based on the first inspection data and the second inspection data.
  11. 11. A computer device comprising a processor and a memory, wherein the memory has stored therein at least one program code that is loaded and executed by the processor to cause the computer device to implement the method of inspection of an oil and gas production system according to any one of claims 1 to 9.
  12. 12. A computer readable storage medium having stored therein at least one program code loaded and executed by a processor to cause a computer to implement a method of inspection of an hydrocarbon production system as claimed in any one of claims 1 to 9.
  13. 13. A computer program product, characterized in that it has stored therein at least one computer instruction that is loaded and executed by a processor to cause the computer to implement a method of inspection of an oil and gas production system according to any one of claims 1 to 9.

Description

Inspection method, device, equipment and storage medium of oil and gas exploitation system Technical Field The embodiment of the application relates to the field of oil and gas exploitation, in particular to a patrol method, device and equipment of an oil and gas exploitation system and a storage medium. Background In the process of oil and gas exploitation, the method plays an important role in the inspection of parameters of an oil and gas exploitation system. In the inspection process, parameters of oil gas exploitation equipment in the oil gas exploitation system are inspected according to specified inspection time and inspection route, abnormality of the equipment parameters can be found in time through inspection, and abnormal conditions are processed in time, so that stable operation of the oil gas exploitation system is ensured. For example, the hydrocarbon production equipment may include a plurality of inspection points, which may include instrumentation, valve switches, etc. of the hydrocarbon production equipment, and by inspecting the parameters of the instrumentation, valve switches, etc., it may be confirmed whether the equipment parameters of the hydrocarbon production system are in a normal state. Disclosure of Invention The application provides a method, a device, equipment and a storage medium for inspecting an oil gas exploitation system, which improve the inspection efficiency and the inspection accuracy of the oil gas exploitation system. In a first aspect, there is provided a method of inspection of an oil and gas production system, the method comprising: acquiring basic information associated with a patrol point, wherein the patrol point comprises equipment components to be patrol in an oil and gas exploitation system, the basic information represents the association relation between the patrol point and patrol equipment, and the patrol equipment comprises image acquisition equipment and equipment sensors; Generating first inspection information by utilizing the basic information and the inspection task of the inspection point; Performing conflict detection on the first inspection information, and optimizing the first inspection information based on a conflict detection result to obtain second inspection information; The inspection points are inspected based on the second inspection information, first inspection data and second inspection data are obtained, the first inspection data comprise inspection images of the inspection points collected by the image collecting equipment, and the second inspection data comprise information of the inspection points collected by the equipment sensor; And generating a patrol result based on the first patrol data and the second patrol data. In a second aspect, there is provided a patrol device for an oil and gas production system, the device comprising: The system comprises an acquisition module, a detection module and a detection module, wherein the acquisition module is used for acquiring basic information associated with a detection point, the detection point comprises equipment components to be detected in an oil gas exploitation system, the basic information represents the association relation between the detection point and detection equipment, and the detection equipment comprises image acquisition equipment and an equipment sensor; the generation module is used for generating first inspection information by utilizing the basic information and the inspection task of the inspection point; The optimizing module is used for carrying out conflict detection on the first inspection information, optimizing the first inspection information based on a conflict detection result and obtaining second inspection information; The inspection module is used for inspecting the inspection points based on the second inspection information to obtain first inspection data and second inspection data, wherein the first inspection data comprises inspection images of the inspection points acquired by the image acquisition equipment, and the second inspection data comprises information of the inspection points acquired by the equipment sensor; The inspection module is further used for generating an inspection result based on the first inspection data and the second inspection data. In one possible implementation manner, the first inspection information includes a first inspection path and a first inspection time of the inspection point, and the generating module is configured to configure the first inspection time of the inspection point by using an inspection task of the inspection point, and generate the first inspection path based on the first inspection time and the basic information. In one possible implementation manner, the result of the conflict detection includes a first conflict detection result, the optimization module is configured to perform conflict detection on the first inspection time of the inspection point to obtain the first conflict detection res