CN111582549A - Power station monitoring and rush-repair system based on GIS - Google Patents

Abstract

The invention relates to a GIS-based power station monitoring and rush-repair system, which comprises: the monitoring data receiving module is used for acquiring real-time monitoring data of equipment of the power station and the corresponding power station position; the data analysis module is used for analyzing and processing the real-time monitoring data and marking the data which do not meet the preset conditions as faults; the work order creating module is used for automatically creating a fault work order according to the data marked as the fault; the work order display module is used for displaying a fault work order icon on the GIS map according to the power station position corresponding to the fault work order; the real-time position acquisition module is used for acquiring the real-time positions of all qualified emergency repair teams in the area where the power station is located corresponding to the fault data; and the work order dispatching module is used for dispatching the fault work orders to the rush-repair team with the shortest distance to the corresponding power station. The power station equipment monitoring system can realize real-time monitoring of the power station equipment, timely carries out fault rush repair when monitoring the fault of the power station equipment, and improves the reliability of power supply of a power system.

Description

Power station monitoring and rush-repair system based on GIS

Technical Field

The invention relates to the technical field of power stations, in particular to a GIS-based power station monitoring and emergency repair system.

Background

In an electric power system, power stations are distributed at multiple points, have wide areas and multiple devices, are complex in operation environment and are greatly influenced by external force damage and natural disasters, so that various faults often occur due to natural reasons or artificial reasons, and the reliability of the electric power system is seriously influenced. The safety of the equipment is the basis of safe, reliable and stable operation of each power station, the power station equipment is effectively and accurately monitored and diagnosed, the power station equipment is an important way for improving the power supply thinkability and power operation intellectualization level, the rapid and accurate power station equipment fault diagnosis and the effective fault first-aid repair can improve the power station equipment fault processing level, the power failure time caused by power station equipment faults is reduced, and the power supply reliability of a power system is improved. Therefore, automatic monitoring and timely fault repair of the power station equipment become important contents of the work of the power system.

Disclosure of Invention

The invention aims to overcome at least one defect in the prior art, and provides a GIS-based power station monitoring and emergency repair system, which can realize real-time monitoring of power station equipment, timely carry out fault emergency repair when the power station equipment is monitored to be in fault, and improve the reliability of power supply of a power system.

The technical scheme adopted by the invention is as follows:

the utility model provides a power station monitoring and salvagees system based on GIS includes:

the monitoring data receiving module is used for acquiring real-time monitoring data of equipment of the power station and the position of the power station corresponding to the monitoring data;

the data analysis module is used for analyzing and processing the real-time monitoring data and marking the data which do not meet the preset conditions as faults;

the work order creating module is used for automatically creating a fault work order according to the data marked as the fault;

the work order display module is used for displaying a fault work order icon on a GIS map at the power station position corresponding to the fault work order;

the real-time position acquisition module is used for acquiring the real-time positions of all qualified emergency repair teams in the area where the power station is located corresponding to the fault data;

the real-time position display module is used for displaying all emergency repair team icons on a GIS map according to the real-time positions of all emergency repair teams, and the colors of all emergency repair team icons are the same;

and the work order distributing module is used for distributing the fault work orders to the rush-repair team with the shortest distance to the corresponding power station according to the power station position corresponding to the fault work orders.

The monitoring data receiving module receives data obtained by monitoring power station equipment in real time and a power station position corresponding to the monitoring data, the data analysis module is right for analyzing and processing the real-time monitoring data, whether the power station equipment has a fault or not can be found in time, when the power station equipment has the fault, the work order creating module automatically creates a fault work order and delivers the fault work order to the work order distribution module to distribute the fault work order to a rush-repair team closest to the corresponding power station, and therefore timely and effective rush-repair can be carried out on the equipment with the fault, and the working efficiency is improved.

Further, the real-time position acquisition module is further configured to acquire a real-time position of the emergency repair team on the emergency repair road, where the power station distance corresponding to the abnormal work order is shortest; the real-time position display module is also used for displaying emergency repair team icons on the GIS map according to the real-time positions of the emergency repair teams on the emergency repair roads, and the colors of the emergency repair team icons are different from those of other emergency repair team icons.

The real-time position acquisition module acquires the real-time position of the rush-repair team receiving the fault work order in real time, and the real-time position acquisition display module displays a rush-repair team icon on a GIS map of the real-time position of the rush-repair team, so that the real-time position of the rush-repair team can be monitored in real time.

Further, the analyzing and processing of the real-time monitoring data by the data analyzing module is to compare the acquired real-time monitoring data with a boundary value of a preset normal threshold range, and if the acquired real-time monitoring data exceeds the positive and negative threshold ranges, the real-time monitoring data is marked as a fault.

Further, the data analysis module further performs fault reason analysis on the data marked as faults and generates a fault reason analysis result.

The data analysis module also comprises a data analysis module for analyzing the fault reason of the data marked as the fault and generating a fault reason analysis result, so that the rush-repair team can quickly know the reason of the equipment fault and the efficiency of rush-repair team to rush-repair the fault can be improved to a certain extent.

Further, the work order display module is further used for displaying fault data and a fault reason analysis result corresponding to the fault work order when the fault work order icon is judged to be clicked.

Further, the system further comprises: and the route generating module is used for automatically generating an optimal emergency repair route according to the power station position corresponding to the data marked as the fault and the emergency repair team with the shortest distance to the power station, and sending the optimal emergency repair route to the emergency repair team.

The route generation module automatically generates an optimal emergency repair route for the emergency repair team, so that time wasted by the emergency repair team due to detour or other reasons can be saved.

Further, the system further comprises: and the help-seeking receiving module is used for receiving help-seeking information of the emergency maintenance team in the emergency maintenance process of the power station equipment.

Further, the system further comprises: and the resource scheduling module is used for allocating the needed emergency repair personnel or emergency repair materials for the emergency repair team according to the help seeking information.

The emergency repair team can send help seeking information to the system when needing help in the emergency repair process, and the help seeking receiving module receives the help seeking information is handed over to the resource allocation module after, and the resource allocation module is according to the help seeking information allocates its required manpower or goods and materials for the emergency repair team, thereby makes the emergency repair team can avoid delaying the problem of trouble emergency repair because of personnel are not enough or goods and materials are not enough in the emergency repair process.

Furthermore, the system also comprises a real-time monitoring module which is used for acquiring the time of the emergency repair team reaching the corresponding power station, the fault reason reported through field investigation and the predicted repair time.

Further, the real-time monitoring data comprises transformer monitoring data, insulation monitoring data, partial discharge monitoring data, circuit breaker monitoring data, arrester monitoring data and environment monitoring data.

Compared with the prior art, the invention has the beneficial effects that:

(1) this system is through carrying out real-time supervision to power station equipment, can in time discover power station equipment breaks down, when discovering power station equipment trouble, in time establish the work order and dispatch to nearest rush repair team and salvage to realize real-time supervision power station equipment and in time salvage to trouble equipment.

(2) The system can realize real-time monitoring of the rush-repair team by acquiring the real-time position of the rush-repair team.

(3) The system can save the time consumed by the rush-repair team on the rush-repair road and improve the rush-repair efficiency by transmitting the optimal rush-repair route for the rush-repair team.

(4) The system can avoid the problem that the rush-repair team cannot rush-repair timely due to insufficient materials or manpower in the rush-repair process to a certain extent by receiving the help seeking information of the rush-repair team and allocating corresponding resources for the help seeking information.

Drawings

Fig. 1 is an overall block diagram of the system.

Detailed Description

The drawings are for illustrative purposes only and are not to be construed as limiting the patent; for the purpose of better illustrating the embodiments, certain features of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product; it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

The technical solution of the present invention is further described below with reference to the accompanying drawings and examples.

As shown in fig. 1, this embodiment provides a power station monitoring and emergency repair system based on GIS, including:

the monitoring data receiving module is used for acquiring real-time monitoring data of equipment of the power station and the position of the power station corresponding to the monitoring data;

the data analysis module is used for analyzing and processing the real-time monitoring data and marking the data which do not meet the preset conditions as faults;

the work order creating module is used for automatically creating a fault work order according to the data marked as the fault;

the work order display module is used for displaying a fault work order icon on a GIS map at the power station position corresponding to the fault work order;

the real-time position acquisition module is used for acquiring the real-time positions of all qualified emergency repair teams in the area where the power station is located corresponding to the fault data;

the real-time position display module is used for displaying all emergency repair team icons on a GIS map according to the real-time positions of all emergency repair teams, and the colors of all emergency repair team icons are the same;

and the work order distributing module is used for distributing the fault work orders to the rush-repair team with the shortest distance to the corresponding power station according to the power station position corresponding to the fault work orders.

Specifically, the monitoring data receiving module acquires real-time monitoring data of equipment of the power station and the position of the power station corresponding to the monitoring data, the real-time monitoring data comprises transformer monitoring data, insulation monitoring data, partial discharge monitoring data, circuit breaker monitoring data, arrester monitoring data and environment monitoring data, the real-time monitoring data is analyzed and processed by a data analysis module, data which do not meet preset conditions are marked as faults, the data analysis module analyzes and processes the real-time monitoring data, specifically, compares the acquired real-time monitoring data with a boundary value of a preset normal threshold range, and if the boundary value exceeds the positive and negative threshold ranges, the transformer monitoring data is marked as a fault, for example, when the upper oil temperature in the transformer monitoring data is analyzed by the data analysis module to exceed 95 ℃, the transformer monitoring data is marked as a transformer fault; the data analysis module sends the data marked as the fault to a work order creation module, the work order creation module automatically creates a fault work order and a work order display module displays a fault work order icon on a GIS map of a power station position corresponding to the fault work order, wherein the fault work order comprises a transformer fault work order, an insulation fault work order, a partial discharge fault work order, a breaker fault work order and a lightning arrester fault work order; the real-time position acquisition module acquires the real-time positions of all qualified emergency repair teams in the area of the power station according to the power station corresponding to the fault work order after the fault work order is created, and the real-time position display module displays emergency repair team icons on a GIS map according to the real-time positions of all emergency repair teams, wherein the icon is blue in color; the work order distribution module is according to the power station position that the work order corresponds will the power station position contrasts with all real-time positions of salvageing the team, distributes trouble work order to leaving the nearest salvageing team of power station, and will salvage the icon of team and become red. The monitoring data receiving module receives data obtained by monitoring power station equipment in real time and a power station position corresponding to the monitoring data, the data analysis module is right for analyzing and processing the real-time monitoring data, whether the power station equipment has a fault or not can be found in time, when the power station equipment has the fault, the work order creating module automatically creates a fault work order and delivers the fault work order to the work order distribution module to distribute the fault work order to a rush-repair team closest to the corresponding power station, and therefore timely and effective rush-repair can be carried out on the equipment with the fault, and the working efficiency is improved.

In this embodiment, the real-time position obtaining module is further configured to obtain a real-time position of the emergency repair team on the emergency repair road, where the power station distance corresponding to the abnormal work order is the shortest; the real-time position display module is also used for displaying emergency repair team icons on the GIS map according to the real-time positions of the emergency repair teams on the emergency repair roads, and the colors of the emergency repair team icons are different from those of other emergency repair team icons.

In this embodiment, the data analysis module further performs fault cause analysis on the data marked as the fault, and generates a fault cause analysis result.

In this embodiment, the work order display module is further configured to display the fault data and the fault reason analysis result corresponding to the fault work order when it is determined that the fault work order icon is clicked.

Specifically, after the emergency maintenance team closest to the power station corresponding to the fault work order receives the fault work order sent by the work order distribution module, the fault work order icon can be clicked, and after the work order display module judges that the fault work order icon is clicked, the content of the fault work order, including the corresponding power station, fault data and the reason of the specific fault, is displayed; salvage team's real-time position acquisition module can acquire salvage team's real-time position to by real-time position display module will salvage team's real-time position shows this salvage team icon on the GIS map, and the colour of this salvage team icon is become red by blue, salvages team icon and removes along with its removal in real time position on the GIS map. The real-time position acquisition module acquires the real-time position of the emergency repair team receiving the fault work order in real time, and the real-time position acquisition display module displays an emergency repair team icon on a GIS map of the real-time position of the emergency repair team, so that the specific position of the emergency repair team can be monitored in real time; the data analysis module also comprises a data analysis module for analyzing the fault reason of the data marked as the fault and generating a fault reason analysis result, so that the rush-repair team can quickly know the reason of the equipment fault and the efficiency of rush-repair team to rush-repair the fault can be improved to a certain extent.

In this embodiment, the system further includes: and the route generating module is used for automatically generating an optimal emergency repair route according to the power station position corresponding to the data marked as the fault and the emergency repair team with the shortest distance to the power station, and sending the optimal emergency repair route to the emergency repair team.

Specifically, the route generation module carries out route planning according to the position of the power station and the position of the emergency maintenance team with the shortest distance to the power station, compares all planned routes, and selects the route with the shortest time as the optimal emergency maintenance route to be sent to the emergency maintenance team, so that the time wasted by the emergency maintenance team due to detour or other reasons can be saved.

In this embodiment, the system further includes: and the help-seeking receiving module is used for receiving help-seeking information of the emergency maintenance team in the emergency maintenance process of the power station equipment.

In this embodiment, the system further includes: and the resource scheduling module is used for allocating the needed emergency repair personnel or emergency repair materials for the emergency repair team according to the help seeking information.

Specifically, when the emergency maintenance team needs help in the process of performing fault emergency maintenance on the power station equipment, help seeking information can be sent to a system, a help seeking receiving module receives the help seeking information and then sends the help seeking information to a resource allocation module for analysis, and if the help seeking information is that emergency maintenance personnel need to be added, the resource allocation module sends the help seeking information to another spare emergency maintenance team closest to the emergency maintenance team and the spare emergency maintenance team supports the spare emergency maintenance team; and if the help seeking information is that corresponding rush-repair instruments or tools are needed, the resource allocation module sends information to material support personnel to send the rush-repair instruments or tools needed by the rush-repair team to a rush-repair site immediately.

The emergency repair team can send help seeking information to the system when needing help in the emergency repair process, and the help seeking receiving module receives the help seeking information is handed over to the resource allocation module after, and the resource allocation module is according to the help seeking information allocates its required manpower or goods and materials for the emergency repair team, thereby makes the emergency repair team can avoid delaying the problem of trouble emergency repair because of personnel are not enough or goods and materials are not enough in the emergency repair process.

In this embodiment, the system further includes a real-time monitoring module, configured to obtain time when the emergency repair team arrives at the corresponding power station, a fault reason reported through field investigation, and predicted repair time.

Specifically, after the rush-repair team arrives at the corresponding power station, the time of the rush-repair team arriving at the power station, the fault reason reported after the current investigation and the prediction of the fault reason are required to be sent to the system, after the rush-repair is completed, the fault rush-repair completion time is also required to be sent to the system, and the efficiency and the completion rate of the rush-repair team rush-repair are calculated for the system to provide data guarantee.

In this embodiment, the real-time monitoring module is further configured to receive backfilling information of a trouble work order of the emergency maintenance team and verification of a check label of the trouble work order.

Specifically, the information of the fault work order backfill includes actual fault repair completion time and completion results.

It should be understood that the above-mentioned embodiments of the present invention are only examples for clearly illustrating the technical solutions of the present invention, and are not intended to limit the specific embodiments of the present invention. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention claims should be included in the protection scope of the present invention claims.

Claims (10)

1. The utility model provides a power station monitoring and salvagees system based on GIS which characterized in that includes:

the monitoring data receiving module is used for acquiring real-time monitoring data of equipment of the power station and the position of the power station corresponding to the monitoring data;

the data analysis module is used for analyzing and processing the real-time monitoring data and marking the data which do not meet the preset conditions as faults;

the work order creating module is used for automatically creating a fault work order according to the data marked as the fault;

the work order display module is used for displaying a fault work order icon on a GIS map at the power station position corresponding to the fault work order;

the real-time position acquisition module is used for acquiring the real-time positions of all qualified emergency repair teams in the area where the power station is located corresponding to the fault data;

the real-time position display module is used for displaying all emergency repair team icons on a GIS map according to the real-time positions of all emergency repair teams, and the color of all emergency repair team icons is the same color;

and the work order distributing module is used for distributing the fault work orders to the rush-repair team with the shortest distance to the corresponding power station according to the power station position corresponding to the fault work orders.

2. The GIS-based power station monitoring and emergency repair system according to claim 1, wherein the real-time position acquisition module is further configured to acquire a real-time position of the emergency repair team on the emergency repair road, where the power station distance corresponding to the abnormal work order is shortest; the real-time position display module is also used for displaying emergency repair team icons on the GIS map according to the real-time positions of the emergency repair teams on the emergency repair roads, and the colors of the emergency repair team icons are different from those of other emergency repair team icons.

3. The GIS-based power station monitoring and emergency repair system according to claim 1, wherein the data analysis module analyzes the real-time monitoring data by comparing the acquired real-time monitoring data with a boundary value of a preset normal threshold range, and if the acquired real-time monitoring data exceeds the normal threshold range, the real-time monitoring data is marked as a fault.

4. The GIS-based power station monitoring and emergency repair system according to claim 1, wherein the data analysis module further comprises analyzing the data marked as a fault for a fault reason and generating a fault reason analysis result.

5. The GIS-based power station monitoring and emergency repair system according to claim 4, wherein the work order display module is further configured to display fault data and a fault reason analysis result corresponding to the fault work order when it is determined that the fault work order icon is clicked.

6. The GIS-based power station monitoring and emergency repair system of claim 1, further comprising: and the route generating module is used for automatically generating an optimal emergency repair route according to the power station position corresponding to the data marked as the fault and the emergency repair team with the shortest distance to the power station, and sending the optimal emergency repair route to the emergency repair team.

7. The GIS-based power station monitoring and emergency repair system of claim 1, further comprising: and the help-seeking receiving module is used for receiving help-seeking information of the emergency maintenance team in the emergency maintenance process of the power station equipment.

8. The GIS-based power station monitoring and emergency repair system of claim 7, further comprising: and the resource scheduling module is used for allocating the needed emergency repair personnel or emergency repair materials for the emergency repair team according to the help seeking information.

9. The GIS-based power station monitoring and emergency repair system according to claim 1, further comprising a real-time monitoring module for acquiring time of emergency repair team arriving at corresponding power station, failure reason reported through on-site investigation and predicted repair time.

10. The GIS-based power station monitoring and emergency repair system according to claim 1, wherein the real-time monitoring data includes transformer monitoring data, insulation monitoring data, partial discharge monitoring data, breaker monitoring data, arrester monitoring data, and environmental monitoring data.

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