CN114240316A - Safety monitoring control method and system applied to electric power engineering construction - Google Patents

Abstract

The application provides a safety monitoring management and control method and system applied to electric power engineering construction, comprising the following steps: dividing the electric power engineering construction into a plurality of construction areas, and correspondingly setting a geographic fence for each construction area; one or more inspection unmanned aerial vehicles passing identity authentication are configured in the construction area, the inspection unmanned aerial vehicles acquire video images of the construction area and send the video images to the supervision platform, and the supervision platform supervises the construction area according to the video images. Therefore, the staff can observe the video image of the construction area of the electric power engineering construction, so that the real-time monitoring of the electric power engineering construction is realized, the staff is not required to go to the site for supervision, the construction progress and the site condition can be timely and effectively known, and the manpower and the time are effectively saved; in addition, the accuracy of judging the dangerous conditions on the electric power engineering site is improved, the dangerous conditions occurring in the hydroelectric power generation construction can be judged more effectively and rapidly, the countermeasures can be taken in time, and the loss is reduced.

Description

Safety monitoring control method and system applied to electric power engineering construction

Technical Field

The application relates to the technical field of electric power engineering, in particular to a safety monitoring control method and system applied to electric power engineering construction.

Background

The electric power industry is used as a boosting agent of social economy, a sound and perfect electric power engineering is a fundamental guarantee of a social and economic basic matching system, and is an important link for guaranteeing the strong and perfect national power grid.

However, the construction of the electric power engineering is a production place with multiple types and multiple layers of three-dimensional crossing operation, multiple temporary facilities and large change of operation surface, has more unsafe factors and belongs to the high-risk industry; moreover, the site operation is diversified and wide, the mobility of the personnel involved in the construction is large, the caliber of the engineering safety information statistics is disordered, the safety control mostly depends on the traditional means such as the upper-level assault inspection, the staring of the site safety personnel and the like, the safety information transmission is slow, and the error rate is high.

Therefore, there is a need to provide an improved solution to the above-mentioned deficiencies of the prior art.

Disclosure of Invention

An object of the application is to provide a safety monitoring management and control method and system applied to electric power engineering construction, so as to solve or alleviate the problems existing in the prior art.

In order to achieve the above purpose, the present application provides the following technical solutions:

the application provides a safety monitoring control method applied to electric power engineering construction, which comprises the following steps: dividing the electric power engineering construction into a plurality of construction areas, and correspondingly setting a geographic fence for each construction area; and one or more inspection unmanned aerial vehicles passing identity authentication are configured in the construction area, the inspection unmanned aerial vehicles acquire video images of the construction area and send the video images to a supervision platform, and the supervision platform supervises the construction area according to the video images.

Preferably, the dividing the power engineering construction into a plurality of construction areas, and correspondingly setting a geo-fence for each construction area specifically includes: according to the construction project of the electric power engineering construction, the electric power engineering construction is divided into a plurality of different construction areas, and the geographic fences are correspondingly arranged in the plurality of different construction areas respectively.

Preferably, the construction area is configured with one or more inspection unmanned aerial vehicles which pass through identity authentication, specifically: and one or more to-be-configured inspection unmanned aerial vehicles are in communication connection with the supervision platform through the safety interaction gateway so as to perform identity authentication.

Preferably, one or more inspection unmanned aerial vehicles passing identity authentication are configured in the construction area, the inspection unmanned aerial vehicles acquire video images of the construction area and send the video images to a supervision platform, so that the supervision platform supervises the construction area according to the video images, the inspection unmanned aerial vehicles acquire the video images of the construction area and convert the video images into preset protocol signals to be sent to the supervision platform, and the supervision platform converts the received preset protocol signals into video images to monitor the construction area.

The embodiment of the application further provides a safety monitoring control method for electric power engineering construction, which includes: performing geofence setting on a plurality of construction areas divided in the electric power engineering construction; and receiving video images which are configured in the construction area and sent by one or more inspection unmanned aerial vehicles passing through identity authentication, and supervising the construction area according to the video images.

Preferably, the step of respectively setting the geo-fences in the plurality of construction areas divided in the power engineering construction specifically includes: and dividing the electric power engineering construction into a plurality of different construction areas according to preset construction projects, and correspondingly setting the geographic fences for the plurality of different construction areas respectively.

Preferably, the receiving is performed on the video images sent by one or more inspection unmanned aerial vehicles which pass through identity authentication and are configured in the construction area, and the supervision is performed on the construction area according to the video images, specifically: receiving an identity authentication request sent by the inspection unmanned aerial vehicle through a safety interaction gateway, responding to the identification of a unique identification mark contained in the identity authentication request, receiving a video image sent by the inspection unmanned aerial vehicle through the identity authentication of the inspection unmanned aerial vehicle, and supervising the construction area according to the video image.

Preferably, in the receiving of the video images sent by one or more inspection unmanned aerial vehicles which pass through identity authentication and are configured in the construction area, and in the supervision of the construction area according to the video images, receiving a preset protocol signal, converting the preset protocol signal into a video image, and monitoring the construction area according to the video image; and the preset protocol signal is converted and sent by the inspection unmanned aerial vehicle according to the acquired video image.

The embodiment of the application still provides a safety monitoring management and control system for electric power engineering construction, include: the area dividing unit is configured to divide the power engineering construction into a plurality of construction areas, and a geo-fence is correspondingly arranged in each construction area; and the unmanned aerial vehicle configuration unit is configured to configure one or more inspection unmanned aerial vehicles which pass identity authentication in the construction area, and the inspection unmanned aerial vehicles acquire video images of the construction area and transmit the video images to the supervision platform so as to supervise the construction area by the supervision platform according to the video images.

The embodiment of the application still provides a safety monitoring management and control system for electric power engineering construction, include: the fence setting unit is configured to set the geographic fences of a plurality of construction areas divided in the electric power engineering construction; and the monitoring control unit is configured to receive one or more video images which are configured in the construction area and sent by the inspection unmanned aerial vehicle through serious identity, and supervise the construction area according to the video images.

Compared with the closest prior art, the technical scheme of the embodiment of the application has the following beneficial effects:

in the technical scheme that this application provides, through dividing the electric power engineering construction into a plurality of different construction areas, set up the geofence respectively to every construction area, dispose one or many in every construction area and patrol and examine unmanned aerial vehicle through the identity is serious, carry out the video image collection to the construction area in the geofence region by patrolling and examining unmanned aerial vehicle, and send to the supervision platform, supervise the construction area according to the video image that patrols and examines unmanned aerial vehicle and provide by the supervision platform. Therefore, the staff can observe the video image of the construction area of the electric power engineering construction, so that the real-time monitoring of the electric power engineering construction is realized, the staff is not required to go to the site for supervision, the construction progress and the site condition can be timely and effectively known, and the manpower and the time are effectively saved; in addition, the accuracy of judging the dangerous conditions on the electric power engineering site is improved, the dangerous conditions occurring in the hydroelectric power generation construction can be judged more effectively and rapidly, the countermeasures can be taken in time, and the loss is reduced.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the application and, together with the description, serve to explain the application and are not intended to limit the application. Wherein:

fig. 1 is a schematic flow chart of a safety monitoring management and control method applied to electric power engineering construction according to some embodiments of the present application;

fig. 2 is a schematic flow chart of another safety monitoring and control method applied to electric power engineering construction according to some embodiments of the present application;

fig. 3 is a schematic structural diagram of a safety monitoring and control system applied to power engineering construction according to some embodiments of the present application;

fig. 4 is a schematic structural diagram of another safety monitoring and control system applied to power engineering construction according to some embodiments of the present application.

Detailed Description

The present application will be described in detail below with reference to the embodiments with reference to the attached drawings. The various examples are provided by way of explanation of the application and are not limiting of the application. In fact, it will be apparent to those skilled in the art that modifications and variations can be made in the present application without departing from the scope or spirit of the application. For instance, features illustrated or described as part of one embodiment, can be used with another embodiment to yield a still further embodiment. It is therefore intended that the present application cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

In the description of the present application, the terms "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description of the present application but do not require that the present application must be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present application. The terms "connected," "connected," and "disposed" as used herein are intended to be broadly construed, and may include, for example, fixed and removable connections; can be directly connected or indirectly connected through intermediate components; the connection may be a wired electrical connection, a wireless electrical connection, or a wireless communication signal connection, and a person skilled in the art can understand the specific meaning of the above terms according to specific situations.

Exemplary method

Fig. 1 is a schematic flow chart of a safety monitoring management and control method applied to electric power engineering construction according to some embodiments of the present application; as shown in fig. 1, the safety monitoring and control method applied to electric power engineering construction includes:

step S101, dividing the electric power engineering construction into a plurality of construction areas, and correspondingly setting a geo-fence for each construction area;

specifically, according to the construction project of the electric power engineering construction, the electric power engineering construction is divided into a plurality of different construction areas, and the geographic fences are correspondingly arranged in the plurality of different construction areas respectively.

In the embodiment of the application, because the construction range of the power engineering construction is wide and the construction environments are various, the power engineering construction generally comprises a plurality of different construction projects, the construction projects are used as units to divide the construction areas, a virtual fence, namely a geographic fence, is arranged for the construction areas, and the geographic boundaries of the construction projects are divided. When the constructor or the construction equipment with the positioning tag enters or leaves the area of the geo-fence, or moves in the area, the entering or leaving notice and the moving track of the constructor or the construction equipment carrying the positioning tag can be automatically acquired through the geo-fence, so that the real-time monitoring of the constructor or the construction equipment in the construction area is realized.

In addition, through dividing the electric power engineering construction into different construction areas according to the construction project to the geofence is cut apart, the management efficiency to every construction project is effectually improved, prevents the chaotic phenomenon between the different visual function projects.

In this application embodiment, set up fixed floodgate machine at the edge of geofence, make the constructor or the construction equipment of business turn over geofence all pass in and out the construction area through fixed floodgate machine, gather the characteristic image of business turn over constructor or construction equipment by the image acquisition equipment that sets up on fixed floodgate machine, and transmit to the basic station through the supporting wireless transmitter with fixed floodgate machine, send to supervision platform by the basic station, realize the remote monitoring to business turn over construction area's constructor or construction equipment, effectively improve the personnel to the electric power job site, the management and control of equipment, the dispatch, only allow specific personnel, equipment business turn over, reduce the personnel flow in construction area, improve job site's security.

In the embodiment of the application, the fixed gate machines are multiple, and the multiple fixed gate machines are circumferentially arranged along the geographic fence of the construction area; correspondingly, the wireless transmitters are multiple, and the wireless transmitters are in one-to-one correspondence with the fixed gates. Therefore, by arranging the plurality of fixed gate machines in the circumferential direction of the geographic fence, personnel and equipment in electric power engineering construction can enter and exit the infrastructure construction site from different directions as required, meanwhile, the personnel and equipment are shunted, the personnel and equipment are prevented from being too high in density, the accident possibility of the infrastructure construction site is reduced, the infrastructure construction safety is improved, and the construction efficiency is improved.

In some optional embodiments, the fixed gate comprises: personnel gate and equipment gate; the personnel gate and the equipment gate are arranged in parallel and are connected with the supervision platform; correspondingly, the image acquisition device comprises: the first image acquisition equipment and the second image acquisition equipment are respectively arranged corresponding to the personnel gate and the equipment gate so as to respectively acquire characteristic images of constructors to be treated through the personnel gate and acquire the characteristic images of the constructors to be treated through the equipment gate.

Through setting up personnel floodgate machine and equipment floodgate machine side by side, can be equipped with a wireless transmitter can, reduce cost simultaneously, through personnel floodgate machine and equipment floodgate machine side by side set up, when construction equipment followed the vehicle-mounted personnel, can make the vehicle-mounted personnel can construction equipment pass through simultaneously from personnel floodgate machine, equipment floodgate machine respectively, effectual raising the efficiency, avoid blocking up.

In a specific example, the first image acquisition device acquires a head image of a constructor to be passed through the personnel gate, and transmits the head image to the base station through the wireless transmitter so as to be transmitted to the supervision platform by the base station in real time. Further, the supervision platform receives the head image sent by the base station, determines that a corresponding constructor who is to pass through the personnel lock wears a safety helmet, and controls the personnel lock to be opened.

In the embodiment of the application, on the capital construction site, a constructor can carry out extremely effective safety protection on the constructor by wearing the safety helmet. When a constructor is about to enter a capital construction site to work, head images of the constructor passing through a personnel gate are collected through first image collecting equipment, the collected head images are sent to a supervision platform, the supervision platform confirms whether the corresponding constructor wears a safety helmet or not according to the head images, and if the constructor does not wear the safety helmet, a warning is sent out through the personnel gate; if the constructor wears the safety helmet, the remote control personnel floodgate machine is opened to enable the constructor to pass through. Therefore, the safety protection of personnel in the capital construction site is effectively improved, and the safety is improved.

In another specific example, the second image acquisition device acquires the license plate image of the construction equipment to be passed through the equipment gate, and transmits the license plate image to the base station through the wireless transmitter so as to be transmitted to the supervision platform by the base station in real time. Further, the monitoring platform receives the license plate image sent by the base station, determines that the license plate number of the corresponding construction equipment to pass through the equipment gate exists in the remote monitoring platform, and controls the equipment gate to be opened.

In the embodiment of the application, each piece of equipment and each vehicle entering and exiting a capital construction site are recorded in the supervision platform in advance, the license plate number of the equipment and the vehicle is recorded into the supervision platform, when the construction equipment enters and exits the equipment gate, the license plate image is collected and sent to the supervision platform, the supervision platform automatically judges whether the vehicle number is legal (pre-recorded), and if the vehicle number is legal, the supervision platform remotely controls the equipment gate to be opened. If the vehicle number is an illegal number (strange license plate number), an alarm is sent out through the equipment gate. The personnel gate machine and the equipment gate machine are remotely controlled through the supervision platform, the number of field construction personnel is reduced, labor cost can be effectively reduced, and error probability is reduced.

S102, configuring one or more inspection unmanned aerial vehicles passing identity authentication in a construction area; the video images of the construction area are collected by the inspection unmanned aerial vehicle and are sent to the supervision platform, and the construction area is supervised by the supervision platform according to the video images.

Specifically, one or more unmanned aerial vehicles that patrol and examine that wait to dispose carry out communication connection through safe mutual gateway and supervision platform to carry out authentication. Therefore, the supervision platform carries out identity authentication on the inspection unmanned aerial vehicle to be accessed through the safety interaction gateway, and communicates with the inspection unmanned aerial vehicle passing through the identity authentication, so that the equipment access and data transmission safety is improved.

In the embodiment of the application, each inspection unmanned aerial vehicle has a unique identity authentication representation, namely a unique identification mark, and when the inspection unmanned aerial vehicle is accessed to the supervision platform, an identity authentication request is sent to the supervision platform; the supervision platform receives the identity authentication request and confirms whether the unique identification mark contained in the identity authentication request is prestored in the supervision platform, if the unique identification mark contained in the identity authentication request sent by the inspection unmanned aerial vehicle exists in the supervision platform and is consistent with the unique identification mark, the inspection unmanned aerial vehicle passes through the identity authentication of the inspection unmanned aerial vehicle, and if not, the inspection unmanned aerial vehicle is considered as illegal equipment and is not accessed.

In some optional embodiments, the patrol and examine unmanned aerial vehicle gathers the video image in construction area to convert the video image into and predetermine protocol signal and send to supervision platform, convert into the video image according to the predetermined protocol signal that receives by supervision platform, in order to monitor the construction area.

In the embodiment of the application, after the patrol unmanned aerial vehicle collects the video image of the construction area, the video image is converted into a time-sharing long-term evolution air interface protocol signal and sent to the base station, and the base station converts the obtained time-sharing long-term evolution air interface protocol signal into a base station signal and sends the base station signal to the supervision platform; and the supervision platform converts the obtained base station signals into video images, so that the construction area is monitored. Therefore, the staff can monitor the construction site of the electric power engineering in real time by observing the video image of the construction area of the electric power engineering construction, so that the staff is not required to monitor the site, and the labor and the time are effectively saved.

This application embodiment sets up geofence respectively to every construction area through dividing the electric power engineering construction into a plurality of different construction areas, configures one or many in every construction area and patrols and examines unmanned aerial vehicle through the identity is serious, carries out the video image collection to the construction area in the geofence region by patrolling and examining unmanned aerial vehicle to send to supervision platform, supervise the construction area according to patrolling and examining the video image that unmanned aerial vehicle provided by supervision platform. Therefore, the staff can observe the video image of the construction area of the electric power engineering construction, so that the real-time monitoring of the electric power engineering construction is realized, the staff is not required to go to the site for supervision, the construction progress and the site condition can be timely and effectively known, and the manpower and the time are effectively saved; in addition, the accuracy of judging the dangerous conditions on the electric power engineering site is improved, the dangerous conditions occurring in the hydroelectric power generation construction can be judged more effectively and rapidly, the countermeasures can be taken in time, and the loss is reduced.

Fig. 2 is a schematic flow chart of a safety monitoring management and control method applied to electric power engineering construction according to some embodiments of the present application; as shown in fig. 2, the safety monitoring and control method applied to electric power engineering construction includes:

step S201, performing geofence setting on a plurality of construction areas divided in the electric power engineering construction;

in some optional embodiments, the step of respectively performing geofence setting on a plurality of construction areas divided in the power engineering construction specifically includes: dividing the electric power engineering construction into a plurality of different construction areas according to preset construction project data, and correspondingly setting the geographic fences for the plurality of different construction areas respectively.

In the embodiment of the present application, step S201 can be implemented by referring to step S101, which is not described herein again.

And S202, receiving video images which are configured in the construction area and pass through identity authentication and sent by one or more inspection unmanned aerial vehicles, and supervising the construction area according to the video images.

In some optional embodiments, the video images sent by one or more polling unmanned aerial vehicles which pass through identity authentication and are configured in the construction area are received, and the construction area is supervised according to the video images, specifically: the identity authentication request sent by the patrol unmanned aerial vehicle is received through the safety interaction gateway, the unique identification mark contained in the identity authentication request is responded to and identified, the video image sent by the patrol unmanned aerial vehicle is received through the identity authentication of the patrol unmanned aerial vehicle, and the construction area is supervised according to the video image.

In a specific example, in the process of receiving video images sent by one or more inspection unmanned aerial vehicles which pass identity authentication and are configured in a construction area, monitoring the construction area according to the video images, receiving a preset protocol signal, converting the preset protocol signal into the video images, and monitoring the construction area according to the video images; wherein, predetermine the agreement signal and convert and send according to the video image of gathering by patrolling and examining unmanned aerial vehicle.

In the embodiment of the present application, step S202 can be implemented by referring to step S102, which is not described herein again.

The safety monitoring management and control method applied to electric power engineering construction provided by the embodiment of the application divides the electric power engineering construction into a plurality of different construction areas, a geo-fence is respectively arranged on each construction area, one or more routing inspection unmanned aerial vehicles with serious identities are configured in each construction area, the routing inspection unmanned aerial vehicles acquire video images of the construction areas in the geo-fence area and send the video images to a supervision platform, and the supervision platform supervises the construction areas according to the video images provided by the routing inspection unmanned aerial vehicles. Therefore, the staff can observe the video image of the construction area of the electric power engineering construction, so that the real-time monitoring of the electric power engineering construction is realized, the staff is not required to go to the site for supervision, the construction progress and the site condition can be timely and effectively known, and the manpower and the time are effectively saved; in addition, the accuracy of judging the dangerous conditions on the electric power engineering site is improved, the dangerous conditions occurring in the hydroelectric power generation construction can be judged more effectively and rapidly, the countermeasures can be taken in time, and the loss is reduced.

Exemplary System

Fig. 3 is a schematic structural diagram of a safety monitoring and control system applied to power engineering construction according to some embodiments of the present application; as shown in fig. 3, the safety monitoring and control system applied to power engineering construction includes:

the area dividing unit 301 is configured to divide the power engineering construction into a plurality of construction areas, and set a geo-fence for each construction area;

the unmanned aerial vehicle configuration unit 302 is configured to configure one or more inspection unmanned aerial vehicles passing identity authentication in the construction area, collect video images of the construction area by the inspection unmanned aerial vehicles, and send the video images to the supervision platform so as to supervise the construction area by the supervision platform according to the video images.

In some optional embodiments, the area dividing unit 301 is further configured to divide the electric power engineering construction into a plurality of different construction areas according to the construction projects of the electric power engineering construction, and set the geo-fences to the plurality of different construction areas respectively.

In some optional embodiments, the unmanned aerial vehicle configuration unit 302 is further configured to divide the power engineering construction into a plurality of different construction areas according to the construction projects of the power engineering construction, and set the geo-fences in the plurality of different construction areas respectively.

In some optional embodiments, the patrol and examine unmanned aerial vehicle gathers the video image in construction area to convert the video image into and predetermine protocol signal and send to the supervision platform, convert into video signal by the supervision platform according to the predetermined protocol signal that receives, in order to monitor the construction area.

The safety monitoring control system applied to electric power engineering construction provided by the embodiment of the application can realize the steps and the flows of any safety monitoring control method applied to electric power engineering construction, and achieves the same technical effects, which are not repeated herein.

Fig. 4 is a schematic structural diagram of a safety monitoring and control system applied to power engineering construction according to some embodiments of the present application; as shown in fig. 4, the safety monitoring and control system applied to power engineering construction includes:

a fence setting unit 401 configured to perform geo-fence setting on a plurality of construction areas divided in the power engineering construction, respectively;

the monitoring and control unit 402 is configured to receive video images sent by one or more inspection unmanned aerial vehicles which pass identity authentication and are configured in the construction area, and supervise the construction area according to the video images.

In some optional embodiments, the fence setting unit 401 is further configured to divide the power engineering construction into a plurality of different construction areas according to a preset construction project, and set the geo-fences to the plurality of different construction areas respectively.

In some optional embodiments, the monitoring management and control unit 402 is further configured to receive, through the security interaction gateway, an identity authentication request sent by the inspection unmanned aerial vehicle, receive, through the identity authentication of the inspection unmanned aerial vehicle, a video image sent by the inspection unmanned aerial vehicle in response to recognizing the unique identification included in the identity authentication request, and supervise the construction area according to the video image.

In some optional embodiments, the monitoring management and control unit 402 receives a preset protocol signal, converts the preset protocol signal into a video image, and monitors the construction area according to the video image, wherein the preset protocol signal is converted and sent by the inspection unmanned aerial vehicle according to the acquired video image.

The safety monitoring control system applied to electric power engineering construction provided by the embodiment of the application can realize the steps and the flows of any safety monitoring control method applied to electric power engineering construction, and achieves the same technical effects, which are not repeated herein.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (10)

1. The utility model provides a safety monitoring management and control method for electric power engineering construction which characterized in that includes:

dividing the electric power engineering construction into a plurality of construction areas, and correspondingly setting a geographic fence for each construction area;

and one or more inspection unmanned aerial vehicles passing identity authentication are configured in the construction area, the inspection unmanned aerial vehicles acquire video images of the construction area and send the video images to a supervision platform, and the supervision platform supervises the construction area according to the video images.

2. The safety monitoring and control method applied to electric power engineering construction according to claim 1, wherein the electric power engineering construction is divided into a plurality of construction areas, and a geo-fence is correspondingly set for each construction area, specifically: according to the construction project of the electric power engineering construction, the electric power engineering construction is divided into a plurality of different construction areas, and the geographic fences are correspondingly arranged in the plurality of different construction areas respectively.

3. The safety monitoring and control method applied to power engineering construction according to claim 1, wherein one or more inspection unmanned aerial vehicles passing identity authentication are configured in the construction area, and specifically the method comprises the following steps: and one or more to-be-configured inspection unmanned aerial vehicles are in communication connection with the supervision platform through the safety interaction gateway so as to perform identity authentication.

4. The safety monitoring and control method applied to power engineering construction according to any one of claims 1 to 3, wherein one or more inspection unmanned aerial vehicles passing identity authentication are configured in the construction area, the inspection unmanned aerial vehicles acquire video images of the construction area and transmit the video images to a supervision platform, so that the supervision platform supervises the construction area according to the video images, the inspection unmanned aerial vehicles acquire the video images of the construction area, convert the video images into preset protocol signals and transmit the preset protocol signals to the supervision platform, and the supervision platform converts the preset protocol signals into video images according to the received preset protocol signals so as to monitor the construction area.

5. The utility model provides a safety monitoring management and control method for electric power engineering construction which characterized in that includes:

performing geofence setting on a plurality of construction areas divided in the electric power engineering construction;

and receiving video images which are configured in the construction area and sent by one or more inspection unmanned aerial vehicles passing through identity authentication, and supervising the construction area according to the video images.

6. The safety monitoring and control method for electric power engineering construction according to claim 5, wherein the setting of the geo-fences in the plurality of construction areas divided in the electric power engineering construction is specifically: and dividing the electric power engineering construction into a plurality of different construction areas according to preset construction projects, and correspondingly setting the geographic fences for the plurality of different construction areas respectively.

7. The safety monitoring and control method for electric power engineering construction according to claim 5, wherein the receiving of the video images sent by one or more inspection unmanned aerial vehicles configured in the construction area and passing through identity authentication, and the monitoring of the construction area according to the video images are specifically: receiving an identity authentication request sent by the inspection unmanned aerial vehicle through a safety interaction gateway, responding to the identification of a unique identification mark contained in the identity authentication request, receiving a video image sent by the inspection unmanned aerial vehicle through the identity authentication of the inspection unmanned aerial vehicle, and supervising the construction area according to the video image.

8. The safety monitoring and control method for electric power engineering construction according to any one of claims 5 to 7, wherein in the receiving of the video images sent by one or more inspection unmanned aerial vehicles which pass identity authentication and are configured in the construction area, and in the supervision of the construction area according to the video images, receiving a preset protocol signal, converting the preset protocol signal into a video image, and monitoring the construction area according to the video image; and the preset protocol signal is converted and sent by the inspection unmanned aerial vehicle according to the acquired video image.

9. The utility model provides a safety monitoring management and control system for electric power engineering construction which characterized in that includes:

the area dividing unit is configured to divide the power engineering construction into a plurality of construction areas, and a geo-fence is correspondingly arranged in each construction area;

and the unmanned aerial vehicle configuration unit is configured to configure one or more inspection unmanned aerial vehicles which pass identity authentication in the construction area, and the inspection unmanned aerial vehicles acquire video images of the construction area and transmit the video images to the supervision platform so as to supervise the construction area by the supervision platform according to the video images.

10. The utility model provides a safety monitoring management and control system for electric power engineering construction which characterized in that includes:

the fence setting unit is configured to set the geographic fences of a plurality of construction areas divided in the electric power engineering construction;

and the monitoring control unit is configured to receive one or more video images which are configured in the construction area and sent by the inspection unmanned aerial vehicle through serious identity, and supervise the construction area according to the video images.

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