CN111294243A - Command system and application method thereof - Google Patents

Abstract

The invention relates to a command system and an application method thereof, comprising subsystems which are mutually connected through a network, wherein each subsystem comprises a platform layer, a network layer, a carrier monitoring platform and a perception layer; the platform layer is used for storing and calling data and sending instructions to other subsystems; the network layer is used for realizing network communication between the platform layer and the vehicle monitoring platform; the vehicle monitoring platform is used for setting monitoring equipment and network communication equipment on the basis of a vehicle and is used for monitoring and directing construction; and the sensing layer is used for sensing data generated by the construction individuals in the construction process and sending the data to the carrier monitoring platform. The subsystem is organically integrated to form a complete command system, so that the construction efficiency is effectively improved, the problem of unequal information acquisition in the traditional construction process is solved, the construction risk is reduced, the resource allocation can be optimized, and the complex power construction process is visualized.

Description

Command system and application method thereof

Technical Field

The invention relates to the setting of electric power command, an electric power maintenance command system and an application method thereof

Background

At present, technologies such as smart power grids, distributed energy sources, power distribution networks and micro power grids are rapidly developed, the blueprints of power internet of things are developed, the intelligent and digital construction of the power grids is further accelerated, new problems of safety production caused by technical development and service mode conversion cannot be ignored, and safety guarantee is the most important premise and foundation.

At the present stage, in the electric power safety production management, the field operation management and control mainly depends on human management, the management and control mode is relatively single, the remote intelligent supervision means is incomplete, effective field operation safety management and control technical means and prevention and control measures are lacked, electric power accidents caused by illegal and illegal operations occur, the field operation command system is inconvenient to communicate, and the field operation working condition information is difficult to grasp and flexibly command in time. Is not beneficial to improving the working efficiency and the effect.

Therefore, in the power industry, on the premise of combining the current new technology, how to construct a more real-time and efficient on-site safety management and control system and a convenient command means, who can take advantage in future competition. On the basis, a new command system for electric power operation and an application method thereof need to be created to protect driving for safety production of electric power construction.

Disclosure of Invention

In order to solve the technical problem, a command system and an application method thereof are provided, the technical scheme is that the command system comprises subsystems which are mutually connected through a network, and each subsystem comprises a platform layer, a network layer, a carrier monitoring platform and a sensing layer;

the platform layer is used for storing and calling data and sending instructions to other subsystems;

the network layer is used for realizing network communication between the platform layer and the vehicle monitoring platform;

the vehicle monitoring platform is used for setting monitoring equipment and network communication equipment on the basis of a vehicle and is used for monitoring and directing construction;

the sensing layer is used for sensing data generated by the construction individuals in the construction process and sending the data to the carrier monitoring platform;

the method of using the command system is as follows:

s01, collecting data generated by the construction individuals during construction by the sensing layer, and sending the data to the vehicle monitoring platform;

s02, the vehicle monitoring platform transmits the data collected by the sensing layer to the platform layer through the network layer by using the network communication equipment;

and S03, after the platform layer receives the data, analyzing the data, sending the instruction to the perception layer through the vehicle monitoring platform, and receiving the instruction by the construction individual.

On the basis of the technical scheme, the construction platform further comprises a branch management end which is used for enabling a person in charge of a construction individual to conveniently acquire data of the platform layer for field command.

On the basis of the technical scheme, the platform layer comprises:

the database unit is used for storing data and calling;

the workstation unit is used for processing and analyzing the data acquired by the other subsystems, and uniformly issuing commands to the other subsystems through the server unit and monitoring the commands;

the server unit is used for providing services for other subsystems with authority, and the other subsystems or units in the platform layer can access the data of the database unit through the server;

and the firewall unit is used for providing a network firewall and increasing the network security of the platform layer.

On the basis of the technical scheme, the network layer comprises a narrow-band Internet of things such as NB-Iot and a 4G wireless network, the 4G wireless network is used for communication and data transmission among subsystems and communication among units in each subsystem, and the narrow-band Internet of things realizes data transmission among the units in a specified subsystem.

On the basis of the above technical scheme, the carrier monitoring platform includes:

the vehicle-mounted camera module is used for transmitting the picture of the construction site to the platform layer for monitoring and providing a basis for the command of the platform layer;

the 4G communication module receives and transmits data to other subsystems through a 4G network and carries out communication;

the vehicle-mounted task processing unit is used for processing the instruction sent by the platform layer and receiving data of other units or modules of the platform through the NB-Iot network;

the vehicle-mounted data storage unit is used for storing data collected by other communication and platform units or modules;

the satellite navigation positioning unit is used for determining the position of the satellite navigation positioning unit;

the lighting unit is used for lighting during monitoring or construction;

and the vehicle-mounted charging unit supplies power to each unit in the platform by using photovoltaic power generation equipment outdoors.

On the basis of the technical scheme, the sensing layer comprises a plurality of single sensing modules, which are respectively as follows:

the single camera module is used for providing construction pictures of construction individuals and transmitting the construction pictures to the carrier monitoring platform and the platform layer through the wireless data transmission module;

the satellite positioning module is used for positioning the position of the construction individual;

the elevation sensor module is used for determining the elevation of a construction individual at the location;

the air pressure sensor module is used for determining air pressure data of the location of the construction individual and finally determining the relative height of the construction individual by combining the altitude data of the altitude sensor module;

the wireless communication module is communicated with the carrier monitoring platform, the platform layer or the construction individual by using a 4G network;

and the wireless data transmission module comprehensively utilizes the 4G network and the NB-Iot network to transmit data among the subsystems.

On the basis of the technical scheme, the system further comprises a web management end for controlling and managing the platform layer.

On the basis of the technical scheme, the branch management end obtains the enabling of the server through the field management mobile APP, and obtains the real-time data of each branch system.

Has the advantages that: taking a platform layer as a management end, and providing a solution; the network layer is used as a main relay network transmission means to relay and transmit the data to the platform layer; the vehicle-mounted monitoring platform is used as an information collection and construction monitoring platform, construction data are collected, and a solution can be provided to a certain extent to assist construction; the sensing layer is directly involved in construction, and front-edge information and data are collected during construction to provide reference for continuous construction; the subsystem is organically integrated to form a complete command system, so that the construction efficiency is effectively improved, the problem of unequal information acquisition in the traditional construction process is solved, the construction risk is reduced, the resource allocation can be optimized, and the complex power construction process is visualized.

Drawings

FIG. 1 is a schematic diagram of the architecture of the present invention.

Detailed Description

The first embodiment.

The command system of the embodiment comprises subsystems connected with each other through a network, wherein each subsystem comprises a platform layer 1, a network layer 2, a vehicle monitoring platform 3 and a perception layer 4; the platform layer 1 is used for storing and calling data and sending instructions to other subsystems; the network layer 2 is used for realizing network communication between the platform layer 1 and the vehicle monitoring platform 3; a carrier monitoring platform 3, which is used for setting monitoring equipment and network communication equipment on the basis of a carrier and is used for monitoring and directing construction; and the sensing layer 4 is used for sensing data generated by the construction individuals in the construction process and sending the data to the carrier monitoring platform 3.

The command system is composed of a plurality of subsystems, and at least comprises a platform layer 1, a network layer 2, a vehicle monitoring platform 3 and a perception layer 4.

After receiving the construction task, a task instruction is given by the platform layer 1, the construction individuals know the construction task through the carrier monitoring platform 3, and the tasks are grouped to form a construction team comprising a plurality of construction individuals, and the team takes the action by the responsible person.

After the construction squad orders the carrier monitoring platform 3 to reach the construction destination, a plurality of sensing modules of the sensing layer 4 are started, and data are transmitted to the platform layer 1 through the carrier monitoring platform 3 in real time. The platform layer 1 firstly acquires the position of the carrier monitoring platform 3 through the satellite navigation positioning module, then acquires the position of the construction individual through the positioning unit, and can acquire the specific construction position of the construction individual through data comparison with the database. For example, taking power construction as an example, different high-voltage line towers have independent numbers, each high-voltage line tower is arranged at a certain interval, the platform layer 1 can acquire the accurate position of the carrier monitoring platform 3 and the construction individual body through a multilayer positioning means, and the accurate position of the carrier monitoring platform 3 can be accurately acquired through comparison with the position of each line tower in the database. And by combining the altitude data, the air pressure data and the video information of the sensing layer 4, the construction squad and the position of each construction individual in the squad on the high-voltage line tower can be known.

The sensing modules 7 of the sensing layer are multiple, and the sensing modules 7 at least comprise a module for sensing positions, a module for sensing environments, a module for providing construction images, a module for transmitting data and a module for providing communication.

In order to realize the effect of 'where the construction individuals are specifically constructed by comparing the data in the database with the data in the explanation', a GIS (geographic information system) system of a national power grid can be used for determining the position of each tower, and GPS (global positioning system) information provided by the sensing layer 4 is compared, so that the platform layer 1 can accurately position the position of each construction individual, and management and command are facilitated.

On the basis, each construction individual in the construction squad can be remotely commanded through the platform layer 1, tasks are reasonably and scientifically distributed, necessary guidance is provided when each construction individual carries out construction, construction efficiency can be greatly improved, dangerous construction is avoided to the maximum extent, and transparency is improved while safety is improved.

The main purposes of the platform layer 1 are: data storage, data reading service, data analysis, command issuing and commanding play a role in information understanding, control and decision making. There are also necessary network security means such as network firewall and other necessary devices in the computer room, or other necessary devices, which are not described herein.

The carrier monitoring platform 3 is based on various carriers, modifies the carriers to a certain extent, adds the modified carriers into the system through a network, becomes an important ring, is an important node for the command system to acquire data and information, and also serves as one means for the command system to sense situations.

The carrier can adopt any existing mode, for example, the construction environment with more mountainous terrain, and the carrier can be selected from all-terrain vehicles. In order to fully utilize the advantages of roads in plain areas, vehicles with long cruising ability, such as engineering trucks or pick-up trucks, can be adopted, and a general multipurpose platform represented by IVECO can be adopted during urban operation.

The vehicle monitoring platform 3 includes a vehicle, a 4G communication module, a vehicle task processing unit, a vehicle data storage unit, a satellite navigation positioning unit, an illumination unit, and a vehicle charging unit.

To a plurality of modules or units of carrier monitor platform 3, can carry out direct remote control through 4G communication module by platform layer 1, for example remote control carrier monitor platform 3's on-vehicle module of making a video recording, regularly look over the environmental aspect of construction, can ensure that the construction is gone on in the safe condition, can regard as the effective replenishment of perception layer 4's single camera module again, provide the multi-angle, observe the construction condition of construction squad integratively, make the commander more effective.

The perception layer 4 is realized by a wearing module worn on each construction individual as another means of situation perception. The important function of wearing the module is for the decision-making of platform layer 1 and collect information, and realization function needs include single camera module, satellite positioning module, height above sea level sensor module, baroceptor module basically, wireless communication module, wireless data transmission module.

The wireless data transmission module is mainly used for sending positioning information of construction individuals to the vehicle monitoring platform 3; meanwhile, the technical means of the internet of things can be applied to construction tools of construction teams, for example, a power construction grounding device capable of wirelessly transmitting data and the like, the grounding device transmits device data to a wireless data transmission module through the narrow-band internet of things represented by NB-Iot, the data are sent to a carrier monitoring platform 3 through the transmission module, and finally the data are collected to a platform layer 1, so that the platform layer 1 can know the safety state of construction in real time.

In the present embodiment, the essential components of each subsystem described above are not absolute components or unique components when performing task processing or work. For example, in a rainy area, for power construction or water conservancy construction, a humidity sensor for detecting humidity and a wind speed sensor for monitoring wind speed are likely to be necessary task modules, and when the wind speed sensor works in most urban environments, the function of the air pressure sensor is not obvious, so that the wind speed sensor can not be treated as a necessary module. The corresponding vehicle monitoring platform 3, the platform layer 1 and the network layer 2 are all properly equipped according to different tasks so as to adapt to different working environments. However, as a basic embodiment for implementing the command system, on the premise of implementing the basic functions, the units or modules in the subsystems are not changed fundamentally, so that what auxiliary equipment should be used in each subsystem can refer to the conventional options, and the description of the embodiment is omitted. The above explanation correspondingly applies to the other embodiments described below, and will not be repeated.

Example two.

In the embodiment, on the basis of the first embodiment, the web management terminal 5 is added, and the platform layer 1 is controlled and managed through the web application.

The configuration of the web management terminal 5 in this embodiment may be implemented by the prior art, for example, the management of the web application is implemented by a tomcat server, and specifically, the web management application may be published by a war package and deployed in the tomcat server, and since the tomcat itself also includes an HTTP server, it may also be regarded as a separate web server. The database can be directly connected by the web container to handle dynamic requests.

Remote management of applications can be achieved through web management applications, monitoring platform 3 layer 1 resource utilization, and configuring resources to provide support according to conventional, general construction task needs.

Example three.

This embodiment is based on the first or second embodiment, and the sub management terminal 6 is arranged. The branch management terminal 6 carries out data interaction with the database of the platform layer 1 through the mobile APP, and acquires construction details synchronously with a construction team.

It should be noted that the sub-management terminal 6 realizes data interaction with the platform layer 1 through the customized APP, and facilitates management of construction teams for obtaining construction information and data. The mobile APP can be installed in the intelligent device, and network connection can be conducted through a 4G wireless communication means.

Example four.

The method of using the command system is as follows:

step one, a perception layer 4 collects data generated by construction individuals during construction and sends the data to a carrier monitoring platform 3;

secondly, the vehicle monitoring platform 3 transmits the data collected by the sensing layer 4 to the platform layer 1 through the network layer 2 by utilizing network communication equipment;

and step three, after the platform layer 1 receives the data, analyzing the data, sending the instruction to the perception layer 4 through the carrier monitoring platform 3, and receiving the instruction by the construction individual.

In this embodiment, after each platform is deployed, the method using the command system may be performed from the sensing layer 4 first.

The whole construction process is mainly started from the sensing layer 4, so that the sensing layer 4 is the source of most data in construction. The data that perception layer 4 obtained pass through the relay of carrier monitoring platform 3, convey to platform layer 1 and carry out the analysis, also make platform layer 1 can carry out direct communication with the construction individual, directly issue the instruction to the construction individual, saved traditional intermediate link.

In the deployment, the platform layer 1 and the vehicle monitoring platform 3 are in a stock state, and the perception layer 4 is not effectively deployed in the early period; after the construction task is confirmed, the platform layer 1 issues information and creates a perception layer 4 on the basis of a construction team; the perception layer 4 is moved to a construction site along with the vehicle monitoring platform 3 to be deployed, and at the moment, the deployment is considered to be completed.

Claims (9)

1. The command system and the application method thereof are characterized by comprising subsystems which are mutually connected through a network, wherein each subsystem comprises a platform layer (1), a network layer (2), a vehicle monitoring platform (3) and a perception layer (4);

the platform layer (1) is used for storing and calling data and sending instructions to other subsystems;

the network layer (2) is used for realizing network communication between the platform layer (1) and the vehicle monitoring platform (3);

a carrier monitoring platform (3) which is used for setting monitoring equipment and network communication equipment on the basis of a carrier and is used for monitoring and directing construction;

the sensing layer (4) is used for sensing data generated by the construction individuals in the construction process and sending the data to the carrier monitoring platform (3);

the method of using the command system is as follows:

s01, collecting data generated by the construction individuals during construction by the sensing layer, and sending the data to the vehicle monitoring platform;

s02, the vehicle monitoring platform transmits the data collected by the sensing layer to the platform layer through the network layer by using the network communication equipment;

and S03, after the platform layer receives the data, analyzing the data, sending the instruction to the perception layer through the vehicle monitoring platform, and receiving the instruction by the construction individual.

2. A command system and its application method as claimed in claim 1, characterized in that it further comprises a branch management terminal (6) for enabling the responsible person of the construction individual to obtain the data of the platform layer (1) for on-site command.

3. A command system and its application method according to claim 2, characterized in that the platform layer (1) comprises:

the database unit is used for storing data and calling;

the workstation unit is used for processing and analyzing the data acquired by the other subsystems, and uniformly issuing commands to the other subsystems through the server unit and monitoring the commands;

the server unit is used for providing services for other subsystems with authority, and the other subsystems or units in the platform layer 1 can access the data of the database unit through the server;

and the firewall unit is used for providing a network firewall and increasing the network security of the platform layer 1.

4. A command system and method as claimed in claim 3, wherein the network layer (2) includes narrowband internet of things such as NB-Iot and 4G wireless network, the 4G wireless network is used for communication and data transmission between subsystems and communication between units in each subsystem, and the narrowband internet of things is used for data transmission between units in a given subsystem.

5. The command system and the application method thereof as claimed in claim 4, wherein the vehicle monitoring platform (3) comprises:

the vehicle-mounted camera module is used for transmitting the picture of the construction site to the platform layer (1) for monitoring and providing a basis for the command of the platform layer (1);

the 4G communication module receives and transmits data to other subsystems through a 4G network and carries out communication;

the vehicle-mounted task processing unit is used for processing the instruction sent by the platform layer (1) and receiving data of other units or modules of the platform through an NB-Iot network;

the vehicle-mounted data storage unit is used for storing data collected by other communication and platform units or modules;

the satellite navigation positioning unit is used for determining the position of the satellite navigation positioning unit;

the lighting unit is used for lighting during monitoring or construction;

and the vehicle-mounted charging unit supplies power to each unit in the platform by using photovoltaic power generation equipment outdoors.

6. A command system and its application method as claimed in claim 5, characterized in that, the perception layer (4) comprises a plurality of single perception modules (7), respectively:

the single camera module is used for providing construction pictures of construction individuals and transmitting the construction pictures to the carrier monitoring platform (3) and the platform layer (1) through the wireless data transmission module;

the satellite positioning module is used for positioning the position of the construction individual;

the elevation sensor module is used for determining the elevation of a construction individual at the location;

the air pressure sensor module is used for determining air pressure data of the location of the construction individual and finally determining the relative height of the construction individual by combining the altitude data of the altitude sensor module;

the wireless communication module is used for communicating with the carrier monitoring platform (3), the platform layer (1) or the construction individual by using a 4G network;

and the wireless data transmission module comprehensively utilizes the 4G network and the NB-Iot network to transmit data among the subsystems.

7. A command system and its application method as claimed in claim 1, characterized in that it further comprises a web management end (5) for controlling and managing the platform layer (1).

8. A command system and its application method as claimed in claim 1, characterized in that the branch management terminal (6) obtains the server power by managing the mobile APP on site and obtains the real-time data of each branch system.

9. A method of using a command system, comprising at least the steps of:

s01, collecting data generated by the construction individuals during construction by the sensing layer, and sending the data to the vehicle monitoring platform;

s02, the vehicle monitoring platform transmits the data collected by the sensing layer to the platform layer through the network layer by using the network communication equipment;

and S03, after the platform layer receives the data, analyzing the data, sending the instruction to the perception layer through the vehicle monitoring platform, and receiving the instruction by the construction individual.

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