CN113485235A

CN113485235A - Remote centralized control dispatching system of drainage facility

Info

Publication number: CN113485235A
Application number: CN202110912091.6A
Authority: CN
Inventors: 王昇; 庞偲唯
Original assignee: Shanghai Jiading Xincheng Sewage Treatment Co ltd
Current assignee: Shanghai Jiading Xincheng Sewage Treatment Co ltd
Priority date: 2021-08-10
Filing date: 2021-08-10
Publication date: 2021-10-08

Abstract

The invention discloses a remote centralized control dispatching system of a drainage facility. The system comprises a server, a switch, at least one programmable logic controller and at least one data acquisition device, wherein the switch is in communication connection with the programmable logic controller and the server respectively; the data acquisition equipment is used for acquiring operation data in the pump station, the data acquisition equipment comprises a plurality of sensors, and the operation data comprises sensor data and working state data of a plurality of drainage facilities; the programmable logic controller is used for acquiring the operation data and sending the operation data to the switch; the switch is used for forwarding the operation data to the server; the server is used for receiving the operation data, storing the operation data and carrying out remote centralized control and scheduling on the corresponding drainage facilities according to the operation data. The system can be used for carrying out centralized integrated monitoring and scheduling on the drainage facilities in the pump station.

Description

Remote centralized control dispatching system of drainage facility

Technical Field

The embodiment of the invention relates to the technical field of data processing, in particular to a remote centralized control scheduling system of a drainage facility.

Background

The urban drainage system consists of various drainage facility elements, such as a drainage pipe network, a sewage pump station, a rainwater pump station, a sewage treatment plant, a river channel and the like, wherein the pump station also comprises various drainage facility devices such as a water collecting tank, a water outlet tank, a water inlet and outlet gate, a water pump, a grid machine and the like.

At present, most drainage systems have the problem that the operation conditions of all components of the drainage systems cannot be obtained in time, and pump stations operate relatively independently and lack centralized linkage scheduling of the pump stations.

Disclosure of Invention

The embodiment of the invention provides a remote centralized control scheduling system of a drainage facility, which can perform centralized integrated monitoring on operation data in a drainage system and realize uniform scheduling of drainage.

In a first aspect, an embodiment of the present invention provides a remote centralized control scheduling system for a drainage facility, including: the system comprises a server, a switch, at least one programmable logic controller and at least one data acquisition device, wherein the programmable logic controllers correspond to the data acquisition devices one to one, the switch is in communication connection with the programmable logic controllers and the server respectively, and the programmable logic controllers are in communication connection with the data acquisition devices;

the data acquisition equipment is used for acquiring operation data in the pump station, the data acquisition equipment comprises a plurality of sensors, and the operation data comprises sensor data and working state data of a plurality of drainage facilities;

the programmable logic controller is used for acquiring the operation data and sending the operation data to the switch; the switch is used for forwarding the operation data to the server;

and the server is used for receiving the operation data, storing the operation data and carrying out remote centralized control and scheduling on the corresponding drainage facility according to the operation data.

Further, the sensors comprise a cabinet temperature and humidity sensor, a flow sensor, a water quality monitoring sensor and a liquid level sensor, and the drainage facility comprises a water pump frequency converter, a grating dirt remover, a water inlet and outlet gate and ion deodorization equipment;

the programmable logic controller is respectively in bidirectional communication connection with the water pump frequency converter, the grating dirt separator, the water inlet and outlet gate and the ion deodorization equipment, and is also respectively in communication connection with the cabinet temperature and humidity sensor, the flow sensor, the water quality monitoring sensor and the liquid level sensor;

the cabinet temperature and humidity sensor is used for acquiring temperature and humidity data of a cabinet in a pump station and sending the temperature and humidity data to the programmable logic controller;

the flow sensor is used for collecting flow data of water flow in a pump station and sending the flow data to the programmable logic controller;

the water quality monitoring sensor is used for collecting water quality data in a pump station and sending the water quality data to the programmable logic controller;

the liquid level sensor is used for collecting liquid level data in a pump station and sending the liquid level data to the programmable logic controller;

the water pump frequency converter is used for sending the working state data of the water pump frequency converter to the programmable logic controller and controlling the working state of the water pump frequency converter according to a first state feedback signal sent by the programmable logic controller;

the grid sewage removing machine is used for intercepting garbage in sewage, sending working state data of the grid sewage removing machine to the programmable logic controller and controlling the working state of the grid sewage removing machine according to a second control signal sent by the programmable logic controller;

the water inlet and outlet gate is used for intercepting water flow, sending working state data of the water inlet and outlet gate to the programmable logic controller and controlling the working state of the water inlet and outlet gate according to a third control signal sent by the programmable logic controller;

the ion deodorization equipment is used for eliminating the environmental odor in the pump station, sending the working state data of the ion deodorization equipment to the programmable logic controller, and controlling the ion deodorization equipment according to a fourth control signal sent by the programmable logic controller;

the operational data includes: the temperature and humidity data, the flow data, the water quality data, the liquid level data, the working state data of the water pump frequency converter, the working state data of the grille decontamination machine, the working state data of the water inlet and outlet gate and the working state data of the ion deodorization equipment.

Further, the switches include fabric switches and central control core switches.

Further, the system also comprises at least one remote device which is in communication connection with the server through the switch; the remote equipment is used for acquiring remote data, storing the remote data, reporting the remote data to the central control core switch through the optical fiber switch, and sending the remote data to the server through the central control core switch.

Further, the remote equipment comprises a video monitor, a remote security door lock monitor and a remote inspection terminal; the video monitor is used for monitoring the conditions in the pump station and sending the obtained monitoring data to the server through the switch; the remote security door lock monitor is used for acquiring state data of a control room door lock in a pump station and sending the state data to the server through the switch; the remote inspection terminal is used for generating inspection record data and sending the inspection record data to the server through the switch.

Further, the server comprises a communication server, a video monitoring server and a database server; the communication server is used for carrying out communication in the system; the video monitoring server is used for acquiring and processing monitoring data acquired by the video monitor; and the database server is used for storing all data in the system and performing data circulation on the stored data.

Further, the system further comprises: the central control application equipment is used for performing human-computer interaction; the central control application equipment comprises a real-time data display module, an instruction issuing module, a historical data query module, a data alarm module and a video monitoring module; the real-time data display module is used for displaying the real-time data stored in the database server on a display of the central control application equipment; the instruction issuing module is used for acquiring a preset instruction and a user instruction input by a user, and sending the preset instruction and the user instruction to a communication server so that the communication server sends the instruction to the programmable logic controller to realize remote centralized control and scheduling of each drainage device; the historical data query module is used for searching the historical data of the system from the database server according to a query instruction input by a user and sending the historical data to the real-time data display module so as to display the historical data to the user; the data alarm module is used for determining whether to alarm according to monitoring data, communication data and database data, wherein the monitoring data is acquired from the video monitoring server, the communication data is acquired from the communication server, and the database data is acquired from the database server; and the video monitoring module is used for acquiring monitoring data from the video monitoring server and storing the monitoring data for a user to call and view.

Further, the programmable logic controller is also used for adjusting the working states of the water pump frequency converter, the grille decontamination machine, the water inlet and outlet gate and the ion deodorization equipment according to the control instruction sent by the server or the preset instruction sent by the central control application equipment and the user instruction.

Further, the switch still includes water utilities private network switch, the system still includes drainage monitoring facilities, drainage monitoring facilities passes through water utilities private network switch and well accuse core switch with the server links to each other, drainage monitoring facilities is used for gathering drainage data, and will drainage data send to the server.

Further, the drainage monitoring equipment comprises a pipe network liquid level sensor, a river channel liquid level sensor and a rainfall sensor; the pipe network liquid level sensor is used for acquiring pipe network liquid level data in a drainage area and sending the pipe network liquid level data to the database server; the river channel liquid level sensor is used for collecting river channel liquid level data in a drainage area and sending the river channel liquid level data to the database server; the rainfall sensor is used for collecting rainfall data in the drainage area and sending the rainfall data to the database server.

The embodiment of the invention provides a remote centralized control scheduling system of a drainage facility, which comprises a server, a switch, at least one programmable logic controller and at least one data acquisition device, wherein the programmable logic controllers correspond to the data acquisition devices one by one; the data acquisition equipment is used for acquiring operation data in the pump station, the data acquisition equipment comprises a plurality of sensors, and the operation data comprises sensor data and working state data of a plurality of drainage facilities; the programmable logic controller is used for acquiring the operation data and sending the operation data to the switch; the switch is used for forwarding the operation data to the server; and the server is used for receiving the operation data, storing the operation data and carrying out remote centralized control and scheduling on the corresponding drainage facility according to the operation data.

Drawings

Fig. 1 is a schematic structural diagram of a remote centralized control scheduling system of a drainage facility according to an embodiment of the present invention;

fig. 2 is another schematic structural diagram of a remote centralized control scheduling system of a drainage facility according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of a remote centralized control scheduling system of a drainage facility according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of a remote centralized control scheduling system of a drainage facility according to an embodiment of the present invention;

fig. 5 is a schematic structural diagram of a remote centralized control scheduling system of a drainage facility according to an embodiment of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the invention and are not limiting of the invention. It should be further noted that, for the convenience of description, only some of the structures related to the present invention are shown in the drawings, not all of the structures. In addition, the embodiments and features of the embodiments in the present invention may be combined with each other without conflict. In the following embodiments, optional features and examples are provided in each embodiment, and the individual features described in the embodiments may be combined to form a plurality of alternatives.

Fig. 1 is a schematic structural diagram of a remote centralized control scheduling system for a drainage facility according to an embodiment of the present invention, which is applicable to centralized integrated monitoring and scheduling of drainage facilities.

As shown in fig. 1, the present invention provides a remote centralized control scheduling system for a drainage facility, including: the system comprises a server 110, a switch 120, at least one programmable logic controller 130 and at least one data acquisition device 140, wherein the programmable logic controllers 130 correspond to the data acquisition devices 140 one by one, the switch 120 is respectively in communication connection with the programmable logic controller 130 and the server 110, and the programmable logic controller 130 is in communication connection with the data acquisition device 140; the data acquisition equipment 140 is used for acquiring operation data in the pump station, the data acquisition equipment 140 comprises a plurality of sensors 141, and the operation data comprises sensor data and working state data of a plurality of drainage facilities; the programmable logic controller 130 is configured to obtain the operation data and send the operation data to the switch 120; a switch 120 for forwarding the operation data to the server 110; and the server 110 is configured to receive the operation data, store the operation data, and perform remote centralized control and scheduling on the corresponding drainage facility 142 according to the operation data.

In this embodiment, the server 110 may perform remote centralized control and scheduling on the drainage facilities in multiple pumping stations at the same time, one pumping station may be controlled by one programmable logic controller 130, one programmable logic controller 130 may obtain water flow data collected by the sensor 141 in one pumping station, and one programmable logic controller 130 may control the operating state of the drainage facility 142.

In this embodiment, the server 110 may obtain the operation data collected by the data collection device 140 from the programmable logic controller 130 through the switch 120, and after the operation data is analyzed and processed by the server 110, the operation state of the drainage facility 142 in the data collection device 140 may be controlled through the programmable logic controller 130.

Fig. 2 is another schematic structural diagram of a remote centralized control scheduling system of a drainage facility according to an embodiment of the present invention. As shown in fig. 2, the sensors 141 include a cabinet temperature and humidity sensor 1411, a flow sensor 1412, a water quality monitoring sensor 1413 and a liquid level sensor 1414, and the drainage facility 142 includes a water pump frequency converter 1421, a grid sewage machine 1422, a water inlet and outlet gate 1423 and an ion deodorization device 1424; the programmable logic controller 130 is in bidirectional communication connection with the water pump frequency converter 1421, the grille decontamination machine 1422, the water inlet and outlet gate 1423 and the ion deodorization device 1424, and the programmable logic controller 130 is also in communication connection with the cabinet temperature and humidity sensor 1411, the flow sensor 1412, the water quality monitoring sensor 1413 and the liquid level sensor 1414; a cabinet temperature and humidity sensor 1411, configured to collect temperature and humidity data of a cabinet in a pump station, and send the temperature and humidity data to the programmable logic controller 130; the flow sensor 1412 is configured to collect flow data of water flow in the pump station and send the flow data to the programmable logic controller 130; the water quality monitoring sensor 1413 is used for acquiring water quality data in a pump station and sending the water quality data to the programmable logic controller 130; the liquid level sensor 1414 is used for collecting liquid level data in the pump station and sending the liquid level data to the programmable logic controller 130; the water pump frequency converter 1421 is configured to send the working state data of the water pump frequency converter to the programmable logic controller 130, and control the working state of the water pump frequency converter according to a first state feedback signal sent by the programmable logic controller 130; the grid sewage remover 1422 is configured to intercept garbage in the sewage, send working state data of the grid sewage remover to the programmable logic controller 130, and control a working state of the grid sewage remover according to a second control signal sent by the programmable logic controller; the water inlet and outlet gate 1423 is configured to intercept water flow, send working state data of the water inlet and outlet gate to the programmable logic controller 130, and control a working state of the water inlet and outlet gate according to a third control signal sent by the programmable logic controller 130; the ion deodorization equipment is used for eliminating the environmental odor in the pump station, sending the working state data of the ion deodorization equipment to the programmable logic controller 130, and controlling the ion deodorization equipment according to a fourth control signal sent by the programmable logic controller 130; the operational data includes: temperature and humidity data, flow data, water quality data, liquid level data, working state data of a water pump frequency converter, working state data of a grating dirt separator, working state data of a water inlet and outlet gate and working state data of ion deodorization equipment.

The programmable logic controller 130 is in bidirectional communication connection with the water pump frequency converter 1421, the grid sewage treatment machine 1422, the water inlet and outlet gate 1423, and the ion deodorization device 1424, and is configured to acquire operation data, send the operation data to the server 110 through the switch 120, so that the server 110 analyzes and processes the operation data, and be further configured to control the operating states of the water pump frequency converter 1421, the grid sewage treatment machine 1422, the water inlet and outlet gate 1423, and the ion deodorization device 1424 after the programmable logic controller 130 receives an instruction sent by the server 110. For example, if the server 110 determines that the liquid level in the pumping station is increased according to the operation data, an instruction may be sent to the programmable logic controller 130, so that the programmable logic controller 130 controls the water pump frequency converter 1421 to increase the motor frequency.

The sensor 141 can communicate with the programmable logic controller 130 in a unidirectional manner, that is, the programmable logic controller 130 can only acquire water flow data sent by the sensor 141, and the programmable logic controller 130 partially controls the working state of the sensor 141.

Further, the switch 120 includes a fabric switch 121 and a central core switch 122.

Where fabric switch 121 is coupled to programmable logic controller 130 and central core switch 122 is coupled to server 110.

Fig. 3 is a schematic structural diagram of a remote centralized scheduling system of a drainage facility according to an embodiment of the present invention, as shown in fig. 3, the system further includes at least one remote device 150, and the remote device 150 is communicatively connected to the server 110 through the switch 120; the remote device 150 is configured to acquire remote data, store the remote data, and report the remote data to the central control core switch 122 through the optical fiber switch 121, where the central control core switch 122 sends the remote data to the server 110.

It should be noted that one remote device 150 may obtain remote data from one pumping station, and therefore, the system may include a plurality of remote devices 150, and the remote data of a plurality of pumping stations is obtained through the remote device 150 corresponding to each pumping station.

Further, the remote device 150 comprises a video monitor 151, a remote security door lock monitor 152 and a remote inspection terminal 153; the video monitor 151 is configured to monitor conditions in the pump station, and send the obtained monitoring data to the server 110 through the switch 120; the remote security door lock monitor 152 is used for acquiring state data of a door lock of a control room in a pump station and sending the state data to the server 110 through the switch 120; and a remote patrol terminal 153 for generating patrol record data and transmitting the patrol record data to the server 110 through the switch 120.

The remote data comprises monitoring data, state data and patrol record data. The video monitor 151, the remote security door lock monitor 152 and the remote inspection terminal 153 are respectively connected to the optical fiber switch 121, and are configured to transmit the remote data to the central control core switch 122 through the optical fiber switch 121, and then the central control core switch 122 forwards the remote data to the server 110.

Further, the server 110 includes a communication server 111, a video monitoring server 112 and a database server 113; a communication server 111 for performing communication in the system; the video monitoring server 112 is used for acquiring and processing monitoring data collected by the video monitor 151; and the database server 113 is used for storing all data in the system and performing data flow on the stored data.

The communication server 111 is used for ensuring normal communication in the system, and may be understood as being used for ensuring normal data transmission and instruction transmission among devices in the system. The video monitor 151 may include all cameras in one pump station. The database server 113 may store and transfer data collected by each device in the system.

Fig. 4 is a schematic structural diagram of a remote centralized control scheduling system of a drainage facility according to an embodiment of the present invention, and as shown in fig. 4, the system further includes: the central control application device 160, the central control application device 160 is used for performing human-computer interaction; the central control application device 160 comprises a real-time data display module 161, an instruction issuing module 162, a historical data query module 163, a data alarm module 164 and a video monitoring module 165; a real-time data presentation module 161, configured to present real-time data stored in the database server 113 on a display of the central control application 160; the instruction issuing module 162 is configured to obtain a preset instruction and a user instruction input by a user, and send the preset instruction and the user instruction to the communication server 111, so that the communication server 111 sends the instruction to the programmable logic controller 130, and thus, each drainage facility 142 is remotely and centrally controlled and scheduled; a historical data query module 163, configured to search the historical data of the system from the database server 113 according to a query instruction input by the user, and send the historical data to the real-time data display module 161 to display the historical data to the user; a data alarm module 164, configured to determine whether to alarm according to monitoring data, communication data and database data, where the monitoring data is obtained from the video monitoring server 112, the communication data is obtained from the communication server 111, and the database data is obtained from the database server 113; and the video monitoring module 165 is configured to obtain monitoring data from the video monitoring server 112, and store the monitoring data for the user to call and view.

In one embodiment, the central control application device 160 may be a client terminal device, a user may send an instruction to schedule the system through the central control application device 160, and the user may further obtain historical data and real-time data of the system through the central control application device 160, where the real-time data may be data collected by each device in the system in real time, and the real-time data may include water flow data, remote data, and drainage data.

The programmable logic controller 130 may directly send the collected water flow data to the central control application device 160 through the optical fiber switch 121 and the central control core switch 122, so that the real-time data display module 161 displays the water flow data; the remote device 150 may also send the collected remote data directly to the central application device 160 through the switch 120, so that the real-time data presentation module 161 presents the remote data.

The preset instruction may be an instruction preset in the system, for example, the preset instruction may include an instruction for controlling the closing of the drainage facility 142, and the preset instruction may also be an instruction for acquiring monitoring data. The user command may be a command input by a user, and the user may implement remote centralized control and scheduling of the drainage facility 142 by issuing the user command.

Further, the programmable logic controller 130 is further configured to adjust the operating states of the water pump frequency converter 1421, the grille remover 1422, the water inlet and outlet gate 1423, and the ion deodorization device 1424 according to a control instruction sent by the server 110 or according to a preset instruction sent by the central control application device 160 and a user instruction.

Fig. 5 is a schematic structural diagram of a remote centralized control scheduling system of a drainage facility according to an embodiment of the present invention. As shown in fig. 5, the switch 120 further includes a special water network switch 123, the system further includes a drainage monitoring device 170, the drainage monitoring device 170 is connected to the server 110 through the special water network switch 123 and the central control core switch 122, and the drainage monitoring device 170 is configured to collect drainage data and send the drainage data to the server 110.

In one embodiment, the drainage data may include pipe network liquid level data, river level data, and rainfall data. The drainage monitoring device 180 may send the collected drainage data to the database server 113 through the water service private network switch 123 and the central control core switch 122 for storage, or may directly send the collected drainage data to the real-time data display module 161 in the central control application device 160 through the water service private network switch 123 and the central control core switch 122 for display to the user.

Further, the drainage monitoring device 170 includes a pipe network liquid level sensor 171, a river channel liquid level sensor 172, and a rainfall sensor 173; the pipe network liquid level sensor 171 is used for collecting pipe network liquid level data in a drainage area and sending the pipe network liquid level data to the database server 113; the river channel liquid level sensor 172 is used for collecting river channel liquid level data in the drainage area and sending the river channel liquid level data to the database server 113; and a rainfall sensor 173 for collecting rainfall data in the drainage area and transmitting the rainfall data to the database server 113.

The types and numbers of the pipe network liquid level sensor 171, the river channel liquid level sensor 172 and the rainfall sensor 173 are not particularly limited, and can be selected according to actual conditions.

The remote centralized control scheduling system for the drainage facility, provided by the embodiment of the invention, can realize remote centralized control scheduling on a plurality of pump stations, and can acquire running data of the drainage system in real time through the data acquisition equipment, so that the centralized management on the drainage equipment is facilitated; the situation in the pump station can be known in real time through remote data acquired by remote equipment; the rainfall data, the river channel liquid level data and the pipe network liquid level data are acquired through the monitoring equipment, so that the flood prevention dispatching of the drainage system can be facilitated.

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

Claims

1. A remote centralized control scheduling system for a drainage facility, comprising: the system comprises a server, a switch, at least one programmable logic controller and at least one data acquisition device, wherein the programmable logic controllers correspond to the data acquisition devices one to one, the switch is in communication connection with the programmable logic controllers and the server respectively, and the programmable logic controllers are in communication connection with the data acquisition devices;

2. The system of claim 1, wherein the sensors comprise a cabinet temperature and humidity sensor, a flow sensor, a water quality monitoring sensor and a liquid level sensor, and the drainage facility comprises a water pump frequency converter, a grid sewage disposal machine, an inlet and outlet water gate and an ion deodorization device;

3. The system of claim 1, wherein the switches comprise fabric switches and central control core switches.

4. The system of claim 3, further comprising at least one remote device communicatively coupled to the server via the switch;

the remote equipment is used for acquiring remote data, storing the remote data, reporting the remote data to the central control core switch through the optical fiber switch, and sending the remote data to the server through the central control core switch.

5. The system of claim 4, wherein the remote devices include a video monitor, a remote security door lock monitor, and a remote inspection terminal;

the video monitor is used for monitoring the conditions in the pump station and sending the obtained monitoring data to the server through the switch;

the remote security door lock monitor is used for acquiring state data of a control room door lock in a pump station and sending the state data to the server through the switch;

the remote inspection terminal is used for generating inspection record data and sending the inspection record data to the server through the switch.

6. The system of claim 1, wherein the server comprises a communication server, a video monitoring server, and a database server;

the communication server is used for carrying out communication in the system;

the video monitoring server is used for acquiring and processing monitoring data acquired by the video monitor;

and the database server is used for storing all data in the system and performing data circulation on the stored data.

7. The system of claim 6, further comprising: the central control application equipment is used for performing human-computer interaction;

the central control application equipment comprises a real-time data display module, an instruction issuing module, a historical data query module, a data alarm module and a video monitoring module;

the real-time data display module is used for displaying the real-time data stored in the database server on a display of the central control application equipment;

the instruction issuing module is used for acquiring a preset instruction and a user instruction input by a user, and sending the preset instruction and the user instruction to a communication server so that the communication server sends the instruction to the programmable logic controller to realize remote centralized control and scheduling of each drainage device;

the historical data query module is used for searching the historical data of the system from the database server according to a query instruction input by a user and sending the historical data to the real-time data display module so as to display the historical data to the user;

the data alarm module is used for determining whether to alarm according to monitoring data, communication data and database data, wherein the monitoring data is acquired from the video monitoring server, the communication data is acquired from the communication server, and the database data is acquired from the database server;

and the video monitoring module is used for acquiring monitoring data from the video monitoring server and storing the monitoring data for a user to call and view.

8. The system of claim 7, wherein the programmable logic controller is further configured to adjust the operating states of the water pump frequency converter, the grille decontamination machine, the water inlet/outlet gate and the ion deodorization device according to the control command sent by the server or the preset command and the user command sent by the central control application device.

9. The system of claim 3, wherein the switch further comprises a water service private network switch, the system further comprises a drainage monitoring device, the drainage monitoring device is connected with the server through the water service private network switch and the central control core switch, and the drainage monitoring device is used for collecting drainage data and sending the drainage data to the server.

10. The system of claim 9, wherein the drainage monitoring device comprises a pipe network level sensor, a river level sensor, and a rain sensor;

the pipe network liquid level sensor is used for acquiring pipe network liquid level data in a drainage area and sending the pipe network liquid level data to the database server;

the river channel liquid level sensor is used for collecting river channel liquid level data in a drainage area and sending the river channel liquid level data to the database server;

the rainfall sensor is used for collecting rainfall data in the drainage area and sending the rainfall data to the database server.