CN113407589A - Flooding-proof wind booth state display system - Google Patents

Abstract

The invention discloses a flood-proof wind pavilion state display system, which comprises: the system comprises a flood-proof wind booth global state display subsystem, a flood-proof wind booth 3D model data subsystem and a flood-proof wind booth remote control subsystem; the flooding-proof wind booth 3D model data subsystem is used for providing flooding-proof wind booth 3D modeling data; the flood-proof wind booth global state display subsystem is used for displaying the position of the flood-proof wind booth in the subway line map, alarm data, state data and the execution result of the flood-proof wind booth remote control subsystem by combining the subway line map and the flood-proof wind booth 3D modeling data; the invention solves the problem that the existing flood-proof wind pavilion is not displayed visually.

Description

Flooding-proof wind booth state display system

Technical Field

The invention relates to the technical field of wind pavilion monitoring, in particular to a flooding-proof wind pavilion state display system.

Background

The working state, the equipment state, the fault defect and the environmental data of the flood-proof wind booth are recorded and displayed by using the traditional modes of two-dimensional images, table lists, character descriptions and the like, and the display mode is not visual and has the defects of difficult operation and maintenance supervision and the like.

Disclosure of Invention

Aiming at the defects in the prior art, the flood-proof wind pavilion state display system provided by the invention solves the problem that the existing flood-proof wind pavilion is not displayed visually.

In order to achieve the purpose of the invention, the invention adopts the technical scheme that: a flood-proof kiosk status display system, comprising: the system comprises a flood-proof wind booth global state display subsystem, a flood-proof wind booth 3D model data subsystem and a flood-proof wind booth remote control subsystem;

the flooding-proof wind booth 3D model data subsystem is used for providing flooding-proof wind booth 3D modeling data; the flood-proof wind booth global state display subsystem is used for displaying the position of the flood-proof wind booth in the subway line diagram, alarm data, state data and the execution result of the flood-proof wind booth remote control subsystem by combining the subway line diagram and the flood-proof wind booth 3D modeling data.

Further, still include: the system comprises a power supply subsystem, a sensor group, a data processing subsystem and an HBase database;

the output end of the power supply subsystem is respectively connected with the power supply end of the sensor group and the power supply end of the data processing subsystem; the output end of the sensor group is connected with the input end of the data processing subsystem; the output end of the data processing subsystem is connected with an HBase database; the data processing subsystem is used for filtering and calibrating the sensor data of the sensor group to obtain calibration data; and the HBase database is used for storing calibration data.

Further, the sensor data transmitted by the sensor group includes: water level height data, wind pavilion lifting height data, position data and fault data.

Further, still include: a client and a notification subsystem;

the flood-proof wind booth global state display subsystem is used for calling calibration data of an HBase database, processing the calibration data to obtain alarm data and flood-proof wind booth state data, and sending the alarm data to the client; and the client is used for driving the notification subsystem to notify the staff according to the alarm data.

Further, still include: and the data interaction subsystem is used for connecting a third-party subway line map system, and the flood-prevention shelter global state display subsystem calls the subway line map of the third-party subway line map system through the data interaction subsystem.

Further, still include: and the file server is used for storing flooding-proof wind pavilion 3D modeling data required by the flooding-proof wind pavilion 3D model data subsystem.

Further, still include: the MySQL database is used for storing basic attributes of the flood-proof wind booth;

the flood-proof wind booth global state display subsystem is used for calling the basic attributes of the flood-proof wind booth in the MySQL database and combining the subway line map with the basic attributes of the flood-proof wind booth to obtain a distribution map of the flood-proof wind booth; the MySQL database is also used for storing a distribution map of the flood-proof wind booth;

and the distribution map of the flood-proof wind pavilion is used for being combined with 3D modeling data of the flood-proof wind pavilion to obtain the 3D flood-proof wind pavilion on the map displayed by the flood-proof wind pavilion global state display subsystem.

Further, the flooding-proof kiosk 3D model data subsystem is used for establishing a 3D model of the flooding-proof kiosk, and storing data of the 3D model into a file server to obtain flooding-proof kiosk 3D modeling data;

the flooding-proof wind booth 3D model data subsystem is also used for updating and deleting flooding-proof wind booth 3D modeling data in the file server;

the flooding-proof wind booth 3D model data subsystem is also provided with a flooding-proof wind booth 3D modeling data downloading interface and an inquiry interface.

In conclusion, the beneficial effects of the invention are as follows: according to the system, the 3D model of the flood-proof wind pavilion is established through the 3D model data subsystem of the flood-proof wind pavilion, the subway line map is called through the third-party subway line map system, the 3D model of the flood-proof wind pavilion on the subway line map is realized by combining the 3D model of the flood-proof wind pavilion, the subway line map and the sensor data of the sensor group, and various state data of the 3D model on the map can be visually checked.

Drawings

FIG. 1 is a block diagram of a system configuration of a flood-proof kiosk status display system;

FIG. 2 is a detailed circuit of the power subsystem;

FIG. 3 is a detailed circuit of the notification subsystem.

Detailed Description

The following description of the embodiments of the present invention is provided to facilitate the understanding of the present invention by those skilled in the art, but it should be understood that the present invention is not limited to the scope of the embodiments, and it will be apparent to those skilled in the art that various changes may be made without departing from the spirit and scope of the invention as defined and defined in the appended claims, and all matters produced by the invention using the inventive concept are protected.

As shown in fig. 1, a flood-proof booth status display system includes: the system comprises a flood-proof wind booth global state display subsystem, a flood-proof wind booth 3D model data subsystem and a flood-proof wind booth remote control subsystem;

the flooding-proof wind booth 3D model data subsystem is used for providing flooding-proof wind booth 3D modeling data; the flood-proof wind booth global state display subsystem is used for displaying the position of the flood-proof wind booth in the subway line diagram, alarm data, state data and the execution result of the flood-proof wind booth remote control subsystem by combining the subway line diagram and the flood-proof wind booth 3D modeling data.

The system further comprises: the system comprises a power supply subsystem, a sensor group, a data processing subsystem and an HBase database;

the output end of the power supply subsystem is respectively connected with the power supply end of the sensor group and the power supply end of the data processing subsystem; the output end of the sensor group is connected with the input end of the data processing subsystem; the output end of the data processing subsystem is connected with an HBase database; the data processing subsystem is used for filtering and calibrating the sensor data of the sensor group to obtain calibration data; and the HBase database is used for storing calibration data.

Fig. 2 is a detailed circuit of the power subsystem, which converts the 220V commercial power into the direct current for the operation of the sensor group and the data processing subsystem, and includes: resistors R1-R10, a rectifier bridge H1, capacitors C1-C6, triodes Q1-Q4, voltage stabilizing diodes D3 and D5, rectifier diodes D1, D2 and D4, a transformer T1 and a slide rheostat RP 1.

The sensor data transmitted by the sensor group comprises: water level height data, wind pavilion lifting height data, position data and fault data.

The system further comprises: a client and a notification subsystem;

the flood-proof wind booth global state display subsystem is used for calling calibration data of an HBase database, processing the calibration data to obtain alarm data and flood-proof wind booth state data, and sending the alarm data to the client; and the client is used for driving the notification subsystem to notify the staff according to the alarm data.

Fig. 3 is a detailed circuit of the notification subsystem, which can be connected to a speaker at an output end of the notification subsystem, and can perform voice prompt on a worker through the speaker, and the detailed circuit specifically includes: resistors R11-R26, capacitors C7-C14, triodes Q5-Q6, P-channel junction field effect transistors VT 1-VT 2, slide varistors RP 2-RP 3 and amplifiers A1-A2.

The system further comprises: and the data interaction subsystem is used for connecting a third-party subway line map system, and the flood-prevention shelter global state display subsystem calls the subway line map of the third-party subway line map system through the data interaction subsystem.

The system further comprises: and the file server is used for storing flooding-proof wind pavilion 3D modeling data required by the flooding-proof wind pavilion 3D model data subsystem.

The system further comprises: the MySQL database is used for storing basic attributes of the flood-proof wind booth;

the flood-proof wind booth global state display subsystem is used for calling the basic attributes of the flood-proof wind booth in the MySQL database and combining the subway line map with the basic attributes of the flood-proof wind booth to obtain a distribution map of the flood-proof wind booth; the MySQL database is also used for storing a distribution map of the flood-proof wind booth;

and the distribution map of the flood-proof wind pavilion is used for being combined with 3D modeling data of the flood-proof wind pavilion to obtain the 3D flood-proof wind pavilion on the map displayed by the flood-proof wind pavilion global state display subsystem.

The flooding-proof wind booth 3D model data subsystem is used for establishing a 3D model of the flooding-proof wind booth, and storing data of the 3D model into the file server to obtain flooding-proof wind booth 3D modeling data;

the flooding-proof wind booth 3D model data subsystem is also used for updating and deleting flooding-proof wind booth 3D modeling data in the file server;

the flooding-proof wind booth 3D model data subsystem is also provided with a flooding-proof wind booth 3D modeling data downloading interface and an inquiry interface.

The flood-proof wind booth global state display subsystem comprises: the system comprises a front-end display unit, an alarm data pushing module and a data processing unit, wherein the data processing unit is used for processing calibration data to obtain normal data, early warning data, alarm data and current state data of the flooding-proof wind pavilion; the alarm data pushing module sends normal data, early warning data, alarm data and current state data of the flood-proof wind pavilion to the front-end display unit and then pushes the alarm data to the client;

the front-end display unit marks the corresponding stations of the flooding-proof wind pavilion on the map in blue according to normal data, marks the corresponding stations of the flooding-proof wind pavilion on the map in yellow according to early warning data, marks the corresponding stations of the flooding-proof wind pavilion on the map in red according to alarm data, and marks state data on the flooding-proof wind pavilion, so that operators can conveniently check the state data.

After receiving the notification of the driving notification subsystem or according to the red mark of the front-end display unit, the worker operates the lifting button of the flood-proof shelter on the front-end display unit (the operator can remotely control the lifting of the flood-proof shelter by clicking the 'shelter lifting' or 'shelter lifting' button), the flood-proof shelter remote control subsystem receives the operation instruction, checks and executes the instruction, and after execution, feeds the execution result back to the flood-proof shelter global state display subsystem.

The specific working process is as follows:

the water level outside a certain flooding-proof wind booth continuously rises, the data processing subsystem stores various monitoring data of the sensor group into the HBase database, the flooding-proof wind booth global state display subsystem calls up the latest various monitoring data in real time, the flooding-proof wind booth global state display subsystem completes the situation display of all flooding-proof wind booths of corresponding stations based on a subway network diagram, an operator can conveniently check the working states of all flooding-proof wind booths of a certain station, on a system main interface, if the station is marked to be blue, the situation display indicates that the field system equipment and the water level information of the wind booth are normal, and if the station is yellow or red, the water level information of the corresponding station reaches the warning position. And an operator selects a corresponding flooding-proof wind pavilion to carry out remote lifting control on the flooding-proof wind pavilion, and after sending a control command, the flooding-proof wind pavilion remote control subsystem executes corresponding operation after receiving a remote instruction and feeds back the equipment state and the water level information to the flooding-proof wind pavilion global state display subsystem in real time.

Claims (8)

1. A flood-proof booth status display system, comprising: the system comprises a flood-proof wind booth global state display subsystem, a flood-proof wind booth 3D model data subsystem and a flood-proof wind booth remote control subsystem;

the flooding-proof wind booth 3D model data subsystem is used for providing flooding-proof wind booth 3D modeling data; the flood-proof wind booth global state display subsystem is used for displaying the position of the flood-proof wind booth in the subway line diagram, alarm data, state data and the execution result of the flood-proof wind booth remote control subsystem by combining the subway line diagram and the flood-proof wind booth 3D modeling data.

2. The flood kiosk status display system of claim 1, further comprising: the system comprises a power supply subsystem, a sensor group, a data processing subsystem and an HBase database;

the output end of the power supply subsystem is respectively connected with the power supply end of the sensor group and the power supply end of the data processing subsystem; the output end of the sensor group is connected with the input end of the data processing subsystem; the output end of the data processing subsystem is connected with an HBase database; the data processing subsystem is used for filtering and calibrating the sensor data of the sensor group to obtain calibration data; and the HBase database is used for storing calibration data.

3. The flood kiosk status display system of claim 2, wherein the sensor data transmitted by the sensor group comprises: water level height data, wind pavilion lifting height data, position data and fault data.

4. The flood kiosk status display system of claim 1, further comprising: a client and a notification subsystem;

the flood-proof wind booth global state display subsystem is used for calling calibration data of an HBase database, processing the calibration data to obtain alarm data and flood-proof wind booth state data, and sending the alarm data to the client; and the client is used for driving the notification subsystem to notify the staff according to the alarm data.

5. The flood kiosk status display system of claim 1, further comprising: and the data interaction subsystem is used for connecting a third-party subway line map system, and the flood-prevention shelter global state display subsystem calls the subway line map of the third-party subway line map system through the data interaction subsystem.

6. The flood kiosk status display system of claim 1, further comprising: and the file server is used for storing flooding-proof wind pavilion 3D modeling data required by the flooding-proof wind pavilion 3D model data subsystem.

7. The flood kiosk status display system of claim 1, further comprising: the MySQL database is used for storing basic attributes of the flood-proof wind booth;

the flood-proof wind booth global state display subsystem is used for calling the basic attributes of the flood-proof wind booth in the MySQL database and combining the subway line map with the basic attributes of the flood-proof wind booth to obtain a distribution map of the flood-proof wind booth; the MySQL database is also used for storing a distribution map of the flood-proof wind booth;

and the distribution map of the flood-proof wind pavilion is used for being combined with 3D modeling data of the flood-proof wind pavilion to obtain the 3D flood-proof wind pavilion on the subway line map displayed by the flood-proof wind pavilion global state display subsystem.

8. The flooded-proof kiosk status display system of claim 1, wherein said flooded-proof kiosk 3D model data subsystem is used to build a 3D model of the flooded-proof kiosk and store the data of the 3D model into a file server to obtain flooded-proof kiosk 3D modeling data;

the flooding-proof wind booth 3D model data subsystem is also used for updating and deleting flooding-proof wind booth 3D modeling data in the file server;

the flooding-proof wind booth 3D model data subsystem is also provided with a flooding-proof wind booth 3D modeling data downloading interface and an inquiry interface.

Images