CN113746202A - Electric power monitoring system - Google Patents

Abstract

The invention discloses a power monitoring system, comprising: the information acquisition module is used for acquiring power information of the power equipment and the power line, acquiring interval information within an interval range of the power equipment and the power line, and transmitting the power information and the interval information to the information processing module; the information processing module is used for analyzing and obtaining the current operation conditions of the power equipment and the power line according to the power information and the interval information; the trend simulation module is used for performing trend simulation based on the received power information, interval information and current operation working conditions transmitted by the information processing module to generate a simulation result; and the signal management module acquires and displays the current operating condition and the simulation result, and calls a corresponding preset solution based on the current operating condition and the simulation result. The method and the device have the advantages that the trend of the power system can be automatically predicted, the workload of workers is reduced, and the failure rate of the power system is reduced.

Description

Electric power monitoring system

Technical Field

The invention relates to the technical field of power monitoring, in particular to a power monitoring system.

Background

The power monitoring system takes a computer, communication equipment and a measurement and control unit as basic tools, provides a basic platform for real-time data acquisition, on-off state detection and remote control of a power transformation and distribution system, can form any complex monitoring system with detection and control equipment, plays a core role in power transformation and distribution monitoring, can help enterprises eliminate isolated islands, reduce operation cost, improve production efficiency and accelerate abnormal response speed in the power transformation and distribution process.

However, the existing power monitoring system can only collect data of current actual information, and has no system prediction function in the face of equipment operation tendency, so that when a problem occurs in monitored equipment or data, judgment can be made only through personal experience, and due to different capabilities among workers, abnormal data identified by the monitoring system cannot be processed in time, and finally adverse effects are caused.

Disclosure of Invention

The invention provides an electric power monitoring system, which solves the technical problem that part of problems caused by identifying and judging abnormal data only by means of working experience of personnel in the electric power monitoring system in the prior art cannot be processed in time.

The embodiment of the invention provides an electric power monitoring system, which comprises an information acquisition module, an information processing module, a trend simulation module and a signal management module, wherein the information acquisition module is used for acquiring information of a user;

the information acquisition module is electrically connected with the information processing module, acquires electric power information of electric power equipment and an electric power circuit, acquires interval information within an interval range of the electric power equipment and the electric power circuit, and transmits the electric power information and the interval information to the information processing module;

the information processing module is electrically connected with the trend simulation module and analyzes the current operation conditions of the power equipment and the power line according to the power information and the interval information;

the trend simulation module carries out trend simulation based on the received electric power information, the received interval information and the current operation working condition to generate a simulation result;

the signal management module is respectively electrically connected with the information processing module and the trend simulation module, acquires and displays the current operation condition and the simulation result, and calls a corresponding preset solution based on the current operation condition and the simulation result.

Further, the power monitoring system further comprises a total data management platform;

the total data management platform is respectively electrically connected with the trend simulation module and the signal management module, and is used for acquiring and storing the simulation result stored by the trend simulation module, acquiring and storing the calling operation data of the signal management module and setting a tracing label for the acquired simulation result and the calling operation data.

Further, the power monitoring system further comprises a mechanical control module; the mechanical control module is electrically connected with the signal management module, and is used for realizing the on-off of the switch in the interval range of the electric power equipment and the electric power circuit through manual operation and transmitting on-off operation data to the signal management module.

Further, the preset solution is a solution which is stored in advance by the trend simulation module and is determined based on the current operation condition and the on-off operation data of the power equipment and the power line.

Furthermore, the information acquisition module comprises a patrol data acquisition submodule;

the patrol and examine data acquisition submodule is electrically connected with the information processing module, the patrol and examine data acquisition submodule regularly gathers the electric power equipment with the interval within range of electric power circuit place interval information, wherein, interval information at least includes one of the following: thermal imaging data, environmental temperature and humidity data, discharge data, and equipment operating data.

Furthermore, the information acquisition module also comprises an equipment working condition monitoring submodule;

the equipment working condition monitoring submodule is electrically connected with the information processing module, and the equipment working condition detection submodule is used for collecting the power equipment and the power line power information, wherein the power information comprises a voltage value, a current value, load capacity, electric field intensity, gap discharge data and a frequency value of the power equipment or the power line.

Furthermore, the information acquisition module also comprises a video monitoring sub-module;

the video monitoring submodule is electrically connected with the information processing module and is used for collecting environmental information of the electric power equipment and the interval where the electric power circuit is located and collecting surface deformation information of the electric power equipment.

Further, the trend simulation module comprises a trend simulation submodule and a scheme storage submodule;

the trend simulation submodule is electrically connected with the information processing module and conducts trend simulation on the basis of the received electric power information, the received interval information and the current operation working condition transmitted by the information processing module to generate a simulation result;

the scheme storage submodule is electrically connected with the trend simulation submodule and is used for storing the simulation result and the preset solution.

Further, the signal management module comprises a power management platform, a basic information database and a display device;

the power management platform acquires the current operation condition analyzed by the information processing module and controls the display device to display the current operation condition;

the basic information database is used for storing original parameter information of the electric power equipment.

Further, the total data management platform is provided with an ETL tool, and the total data management platform is electrically connected with the trend simulation module through the ETL tool.

The embodiment of the invention discloses an electric power monitoring system, which comprises an information acquisition module, an information processing module, a trend simulation module and a signal management module, wherein the information acquisition module is used for acquiring information of a power grid; the information acquisition module acquires power information of the power equipment and the power line, acquires interval information within an interval range of the power equipment and the power line, and transmits the power information and the interval information to the information processing module; the information processing module analyzes the current operation conditions of the power equipment and the power line according to the power information and the interval information; the trend simulation module carries out trend simulation based on the received power information, interval information and current operation condition transmitted by the information processing module to generate a simulation result; and the signal management module acquires and displays the current operating condition and the simulation result, and calls a corresponding preset solution based on the current operating condition and the simulation result. The method and the device solve the technical problem that part of problems caused by identifying and judging abnormal data only by means of the working experience of personnel in the electric power monitoring system in the prior art cannot be processed in time, and achieve the technical effects of automatically predicting the trend of the electric power system, reducing the workload of the personnel and reducing the failure rate of the electric power system.

Drawings

Fig. 1 is a structural diagram of an electric power monitoring system according to an embodiment of the present invention;

FIG. 2 is a block diagram of another power monitoring system provided by an embodiment of the present invention;

fig. 3 is a structural diagram of an overall data management platform according to an embodiment of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not limiting of the invention. It should be further noted that, for the convenience of description, only some of the structures related to the present invention are shown in the drawings, not all of the structures.

It should be noted that the terms "first", "second", and the like in the description and claims of the present invention and the accompanying drawings are used for distinguishing different objects, and are not used for limiting a specific order. The following embodiments of the present invention may be implemented individually, or in combination with each other, and the embodiments of the present invention are not limited in this respect.

Fig. 1 is a structural diagram of a power monitoring system according to an embodiment of the present invention.

As shown in fig. 1, the power monitoring system includes an information acquisition module 10, an information processing module 20, a trend simulation module 30, and a signal management module 40.

The information acquisition module 10 is electrically connected with the information processing module 20, and the information acquisition module 10 acquires power information of the power equipment and the power line, acquires interval information within an interval range of the power equipment and the power line, and transmits the power information and the interval information to the information processing module 20.

Specifically, the power information acquired by the information acquisition module 10 at least includes a voltage value, a current value, a load capacity, an electric field strength, gap discharge data, a frequency value, and the like of the power device or the power line, and also includes surface deformation information of the power device, the interval information at least includes thermal imaging data, environmental temperature and humidity data, discharge data, device operation data, and the like in an interval range where the power device and the power line are located, and the power information and the interval information may be acquired in the form of picture data, numerical data, or video data, which is not limited herein.

The information processing module 20 is electrically connected to the trend simulation module 30, and the information processing module 20 analyzes the current operating conditions of the power equipment and the power line according to the power information and the interval information.

Specifically, the information processing module 20 includes a system host, and is configured to receive various pieces of power information and interval information acquired by the information acquisition module 10, and further analyze the current operating conditions of the power equipment and the power line according to the received data information, so as to form a master control adjustment effect.

The trend simulation module 30 performs trend simulation based on the received power information, interval information, and current operating condition, and generates a simulation result.

Specifically, the trend simulation module 30 can perform trend simulation according to the power information and the interval information collected by the information collection module 10 and the current operation condition generated by the signal processing module 20, and for example, the trend simulation module 30 can draw an actual curve graph according to the collected power information and the interval information and according to time and a target variable, the target variable can be set as any parameter in the power information or the interval information as required, and simulate and calculate a predicted trend curve graph for the drawn actual curve graph, and generate a simulation result based on the predicted trend curve graph.

The signal management module 40 is electrically connected to the information processing module 20 and the trend simulation module 30, respectively, acquires and displays the current operating condition and the simulation result, and calls a corresponding preset solution based on the current operating condition and the simulation result.

Specifically, in the preset solution storage and trend simulation module 30, the signal management module 40 can call the preset solution corresponding to the current operation condition and the simulation result in the trend simulation module 30 according to the similarity between the current operation condition and the simulation result and the curve of each parameter and the trend curve stored in the trend simulation module 30 in advance, and the signal management module 40 directly uses the preset solution to regulate the on-off condition of the power equipment and the power line through the information processing module 20, so that the effect of automatic adjustment is achieved, and the occurrence of faults is avoided.

The embodiment of the invention solves the technical problem that part of problems caused by identifying and judging abnormal data only by the working experience of personnel in the power monitoring system in the prior art can not be processed in time, and realizes the technical effects of automatically predicting the trend of the power system, reducing the workload of the personnel and reducing the failure rate of the power system.

Fig. 2 is a block diagram of another power monitoring system according to an embodiment of the present invention. Fig. 3 is a structural diagram of an overall data management platform according to an embodiment of the present invention.

Optionally, as shown in fig. 2, the power monitoring system further includes a total data management platform 50; the total data management platform 50 is electrically connected to the trend simulation module 30 and the signal management module 40, and the total data management platform 50 is configured to acquire and store simulation results stored by the trend simulation module 30, acquire and store calling operation data of the signal management module 40, and set a tracing tag for the acquired simulation results and the calling operation data. Alternatively, as shown in fig. 3, the total data management platform 50 is provided with an ETL tool, and the total data management platform 50 is electrically connected with the trend simulation module 30 through the ETL tool.

Specifically, referring to fig. 3, the total data management platform 50 is configured as a cloud, and is capable of receiving a simulation result sent by the trend simulation module 30 and call operation data sent by the signal management module 40, extracting, converting, and loading the simulation result and the call operation data through an Extract-Transform-Load (ETL) tool configured therein, extracting information such as text labels, method steps, and sequences in the simulation result and the call operation data as data sources, extracting information such as text labels, method steps, and sequences in the simulation result and the call operation data, calling method steps in the operation data and remark information of staff for setting up a scheme, setting a trace tag for the data sources, and finally updating the trace tag into the trend simulation module 30.

It should be noted that the total data management platform 50 may be simultaneously connected to a plurality of trend simulation modules 30, and one trend simulation module 30 corresponds to the power equipment and the power line of one area, so that when a similar fault of a power area corresponding to another trend simulation module 30 occurs in the power area corresponding to the one trend simulation module 30, the signal management module 40 can directly read the corresponding preset solution, thereby assisting the worker in predicting a possible fault and selecting a processing mode. Obviously, if the related information recorded by the trend simulation module 30 of two different power regions is completely the same, the information processing module 20 can further automatically process the fault according to the preset solution. By interactively updating the preset solutions in the trend simulation modules 30 of different power regions by using the total data management platform 50, it is possible to completely stop the phenomena such as misoperation occurring to the power equipment and the power line.

Optionally, as shown in fig. 2, the power monitoring system further includes a machine control module 60; the mechanical control module 60 is electrically connected with the signal management module 40, and the mechanical control module 60 is used for manually switching on and off the switch in the interval range where the power equipment and the power line are located, and transmitting on-off operation data to the signal management module 40.

Specifically, the mechanical control module 60 includes a floor switch, a line breaker, a mechanical control switch, and the like, and a worker can directly perform switching on/off of the switch in the interval range where the power equipment and the power line are located through operation of the mechanical control module 60, and meanwhile, in the operation process, the mechanical control module 60 can also read the action and record data of manual operation, that is, the switching on/off operation data, and transmit the switching on/off operation data to the signal management module 40. The signal management module 40 can determine a preset solution according to the received on-off operation data and the obtained current operation condition and simulation result, and send the preset solution to the trend simulation module for storage.

Optionally, the preset solution is a solution that is pre-stored by the trend simulation module 30 and is determined based on the current operating condition and the on-off operation data of the power equipment and the power line.

Specifically, the information acquisition module 10 can acquire power information of the power equipment and the power line and section information of an area where the power equipment and the power line are located, and send the power information and the section information to the information processing module 20, the information processing module 20 obtains a current operation condition based on analysis of the power information and the section information, and after obtaining the current operation condition, a worker pre-judges a fault that may occur in the power system based on own experience and performs on-off operation through the mechanical control module 60 to avoid the occurrence of the fault. The signal management module 40 obtains on-off operation data of the mechanical control module 60 and the current operation condition of the information processing module 20 to determine a solution under the current operation condition, and sends the solution as a preset solution to the trend simulation module 30 for storage.

Optionally, as shown in fig. 2, the information acquisition module 10 includes an inspection data acquisition sub-module 11; the patrol inspection data acquisition submodule 11 is electrically connected with the information processing module 20, and the patrol inspection data acquisition submodule 11 is used for regularly acquiring interval information of an interval range in which the power equipment and the power line are positioned, wherein the interval information at least comprises one of the following components: thermal imaging data, environmental temperature and humidity data, discharge data, and equipment operating data.

Specifically, the patrol inspection data acquisition submodule 11 comprises a patrol inspection robot and a portable monitoring device, and is used for regularly acquiring information such as thermal imaging data, environment temperature and humidity data, discharge data and device operation data in the range of the electric power device and the electric power circuit. Wherein, it contains thermal imaging appearance and video camera to patrol and examine robot self, can gather thermal imaging data and gather other required data with video data's form.

Optionally, as shown in fig. 2, the information acquisition module 10 further includes an equipment condition monitoring submodule 12; the equipment condition monitoring submodule 12 is electrically connected to the information processing module 20, and the equipment condition detecting submodule 12 is configured to collect power information of the power equipment and the power line, where the power information includes a voltage value, a current value, a load capacity, an electric field strength, gap discharge data, and a frequency value of the power equipment or the power line.

Specifically, the equipment condition monitoring submodule 12 includes inherent sensor equipment such as a voltage transformer, a current transformer, a radiation sensor, and a humidity sensor, and can collect data such as a voltage value, a current value, a load capacity, an electric field strength, gap discharge data, and a frequency value of the power equipment and the power line. The equipment condition monitoring submodule 12 is mainly used for monitoring and reading internal data of the power equipment.

Optionally, as shown in fig. 2, the information collecting module 10 further includes a video monitoring sub-module 13; the video monitoring submodule 13 is electrically connected with the information processing module 20, and the video monitoring submodule 13 is used for acquiring environmental information of an interval where the power equipment and the power line are located and acquiring surface deformation information of the power equipment.

Specifically, the video monitoring sub-module 13 includes a night vision camera and an infrared camera, and is equipped with an image analysis module. The video monitoring sub-module 13 monitors the surrounding environment of the power equipment and the power line section through the night vision camera and the infrared camera, monitors the surface shape of the power equipment, analyzes the surface deformation condition of the power equipment through the image analysis module, and outputs the acquired environmental information and the acquired surface deformation information to the information processing module 20. The video monitoring submodule 13 further includes a radar remote sensing imaging device, and the radar remote sensing imaging device can be used for imaging the fine deformation of the power equipment.

The surface of the video monitoring submodule 13 is of a spherical structure, a base of the video monitoring submodule is provided with a rotary base and a driving motor, a night vision camera, an infrared camera and radar remote sensing imaging equipment are integrated on the spherical structure, and the rotary base is driven to rotate for 360 degrees through a driving electrode, so that the equipment is driven to collect relevant data information without dead angles for 360 degrees.

The video monitoring sub-module 13 mainly monitors the surrounding environment of the power equipment and the heat of the power equipment, that is, mainly monitors external data of the power equipment or the power line.

Optionally, as shown in FIG. 2, the trend simulation module 30 includes a trend simulation submodule 31 and a scenario storage submodule 32.

The trend simulation submodule 31 is electrically connected with the information processing module 20, and the trend simulation submodule 31 performs trend simulation based on the received power information, interval information and current operation condition transmitted by the information processing module 20 to generate a simulation result; the scenario storage submodule 32 is electrically connected to the trend simulation submodule 31, and the scenario storage submodule 32 is configured to store the simulation result and the preset scenario.

Specifically, the trend simulation submodule 31 includes a data curve drawing unit, an actual curve drawing unit and a comparison and analysis unit, after the trend simulation submodule 31 receives the power information, the interval information and the current operation condition, the actual curve drawing unit draws an actual curve graph according to time and a target variable, and the target variable can be set as any parameter in the power information or the interval information as required; and then the data curve drawing unit simulates and calculates a predicted trend curve graph (namely the simulation result) according to the data of the target variable and the actual curve graph, and the comparison and analysis unit analyzes and compares the predicted trend curve graph to obtain the simulation result. Illustratively, when certain data in the predicted trend graph breaks a preset threshold, it indicates that a certain fault may occur.

Optionally, the signal management module 40 includes a power management platform 41, a basic information database 42, and a display device 43.

The power management platform 41 acquires the current operation condition analyzed and obtained by the information processing module 20, and controls the display device 43 to display the current operation condition; the basic information database 42 is used to store raw parameter information of the electrical power equipment.

Specifically, the power management platform 41 in the signal management module 40 can obtain the information in the information processing module 20, and the obtained corresponding information is displayed via the display device 43, the display device 43 may be a display screen of the power system in the local area, the basic information database 42 is a basic database of power equipment information, and when the power line is switched on and off and the power equipment is switched on and off by the mechanical control module 60, a worker may call the original parameter information of the power equipment, which is stored in advance in the basic information database 42, for reference by the worker.

In the embodiment of the invention, after data acquisition, data processing and big data fault processing are carried out and manual operation is carried out, the electric power monitoring system can regulate and control the electric power equipment and the electric power circuit in an automatic mode through trend prediction and calling of a preset solution during secondary operation, so that the occurrence of faults is avoided. Particularly, aiming at a data processing mode of a total data management platform, word labels, method steps, sequence and the like are extracted from a data source mainly through ETL tools to simplify the noise of the steps of a scheme, and the traceback labels are judged and set in multiple directions, and the set traceback labels are synchronously updated to trend simulation modules in different power areas, so that the operation steps of preset solutions stored in other trend simulation modules can be completely applied to a local trend simulation module, automatic direct processing is realized when conditions are completely the same, the judgment burden of a worker on faults is relieved, and the decision and processing of the worker on the field conditions can be assisted.

The embodiment of the invention solves the technical problem that part of problems caused by identifying and judging abnormal data only by the working experience of personnel in the power monitoring system in the prior art can not be processed in time, and realizes the technical effects of automatically predicting the trend of the power system, reducing the workload of the personnel and reducing the failure rate of the power system.

In the description of the embodiments of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Finally, it should be noted that the above-mentioned embodiments are only preferred embodiments of the present invention and the technical principles applied. It will be understood by those skilled in the art that the present invention is not limited to the particular embodiments described herein, but is capable of various obvious changes, rearrangements and substitutions as will now become apparent to those skilled in the art without departing from the scope of the invention. Therefore, although the present invention has been described in greater detail by the above embodiments, the present invention is not limited to the above embodiments, and may include other equivalent embodiments without departing from the spirit of the present invention, and the scope of the present invention is determined by the scope of the appended claims.

Claims (10)

1. The power monitoring system is characterized by comprising an information acquisition module, an information processing module, a trend simulation module and a signal management module;

the information acquisition module is electrically connected with the information processing module, acquires electric power information of electric power equipment and an electric power circuit, acquires interval information within an interval range of the electric power equipment and the electric power circuit, and transmits the electric power information and the interval information to the information processing module;

the information processing module is electrically connected with the trend simulation module and analyzes the current operation conditions of the power equipment and the power line according to the power information and the interval information;

the trend simulation module carries out trend simulation based on the received electric power information, the received interval information and the current operation working condition to generate a simulation result;

the signal management module is respectively electrically connected with the information processing module and the trend simulation module, acquires and displays the current operation condition and the simulation result, and calls a corresponding preset solution based on the current operation condition and the simulation result.

2. The power monitoring system of claim 1, further comprising an overall data management platform;

the total data management platform is respectively electrically connected with the trend simulation module and the signal management module, and is used for acquiring and storing the simulation result stored by the trend simulation module, acquiring and storing the calling operation data of the signal management module and setting a tracing label for the acquired simulation result and the calling operation data.

3. The power monitoring system of claim 1, further comprising a machine control module; the mechanical control module is electrically connected with the signal management module, and is used for realizing the on-off of the switch in the interval range of the electric power equipment and the electric power circuit through manual operation and transmitting on-off operation data to the signal management module.

4. The power monitoring system of claim 3, wherein the predetermined solution is a solution pre-stored by the trend simulation module and determined based on current operating conditions and on-off operation data of the power equipment and the power line.

5. The power monitoring system of claim 1, wherein the information collection module comprises an inspection data collection sub-module;

the patrol and examine data acquisition submodule is electrically connected with the information processing module, the patrol and examine data acquisition submodule regularly gathers the electric power equipment with the interval within range of electric power circuit place interval information, wherein, interval information at least includes one of the following: thermal imaging data, environmental temperature and humidity data, discharge data, and equipment operating data.

6. The power monitoring system of claim 1, wherein the information collection module further comprises an equipment condition monitoring submodule;

the equipment working condition monitoring submodule is electrically connected with the information processing module, and the equipment working condition detection submodule is used for collecting the power equipment and the power line power information, wherein the power information comprises a voltage value, a current value, load capacity, electric field intensity, gap discharge data and a frequency value of the power equipment or the power line.

7. The power monitoring system of claim 1, wherein the information collection module further comprises a video monitoring sub-module;

the video monitoring submodule is electrically connected with the information processing module and is used for collecting environmental information of the electric power equipment and the interval where the electric power circuit is located and collecting surface deformation information of the electric power equipment.

8. The power monitoring system of claim 1, wherein the trend simulation module includes a trend simulation submodule and a scenario storage submodule;

the trend simulation submodule is electrically connected with the information processing module and conducts trend simulation on the basis of the received electric power information, the received interval information and the current operation working condition transmitted by the information processing module to generate a simulation result;

the scheme storage submodule is electrically connected with the trend simulation submodule and is used for storing the simulation result and the preset solution.

9. The power monitoring system of claim 1, wherein the signal management module comprises a power management platform, a base information database, and a display device;

the power management platform acquires the current operation condition analyzed by the information processing module and controls the display device to display the current operation condition;

the basic information database is used for storing original parameter information of the electric power equipment.

10. The power monitoring system of claim 2, wherein the overall data management platform is provided with an ETL tool through which the overall data management platform is electrically connected with the trend simulation module.

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