CN203550999U - Flood monitoring device and flood disaster managing system - Google Patents

Abstract

An embodiment of the utility model discloses a flood monitoring device and a flood disaster managing system, wherein the flood monitoring device comprises a radar sensor, a signal processor and a communication device. The radar wave beam of the radar sensor covers a monitoring range. The radar sensor acquires a flowing speed signal and a water level signal in the monitoring range through the reflected radar wave beam. The signal processor is connected with the radar sensor and performs filtering processing and digital signal processing on the flowing speed signal and the water level signal which are acquired by the radar sensor in the monitoring range, thereby acquiring hydrological data in the monitoring range. The communication device is connected with the signal processor and a background monitoring platform respectively and transmits the hydrological data which are acquired by the signal processor in the monitoring range to the background monitoring platform. The flood monitoring device can improve measurement accuracy for the hydrological data without underwater contact.

Description

Flood monitoring device and Flood Disaster Management System

Technical field

The utility model relates to monitoring technique field, relates in particular to flood monitoring device and Flood Disaster Management System.

Background technology

In the process building in informationized society, high-tech product is constantly applied in living scene, for the monitoring technology of flood, be also tending towards ripe, monitoring technology can be applied to various scenes, for example can be applicable to Flood Disaster Management System, by hydrographic datas such as the water level in analysis monitoring range, flows, the hydrographic data in monitoring range is monitored, prevent that city waterlogging from bringing inconvenience to people's daily life, the even safety of threat to life and property.

Existing the monitoring of flood is mainly adopted to the monitoring device of contact (as: bubble type, float-type) under water, or adopt contactless monitoring device (as: ultrasonic sensor), obtain thus hydrographic data analysis.But, owing to for a long time the monitoring device of contact being placed in to water, easily device is caused to loss, and adopt ultrasonic sensor affected by external environment factor, cause measurement data not accurate.

Utility model content

The utility model embodiment provides a kind of flood monitoring device and Flood Disaster Management System, without contacting, can improve the measurement precision to hydrographic data under water.

In order to solve the problems of the technologies described above, the utility model embodiment provides a kind of flood monitoring device, comprising:

Radar sensor, signal processor and communicator, wherein,

The radar beam of described radar sensor covers monitoring range, and described radar sensor obtains flow velocity signal and the water level signal in described monitoring range by the radar beam reflecting;

Described signal processor is connected with described radar sensor, flow velocity signal and water level signal in the described monitoring range that described signal processor obtains described radar sensor are carried out filtering processing and digital signal processing, obtain the hydrographic data in described monitoring range;

Described communicator is connected with described background monitoring platform with described signal processor respectively, and the hydrographic data in the described monitoring range that described communicator obtains described signal processor is sent to described background monitoring platform.

The utility model embodiment also provides a kind of Flood Disaster Management System, comprises background monitoring platform, wherein, also comprises: above-mentioned flood monitoring device;

Wherein, described background monitoring platform is connected with described flood monitoring device, and described background monitoring platform receives and export the hydrographic data in the described monitoring range that described flood monitoring device sends.

Implement the utility model embodiment, there is following beneficial effect:

The radar beam of launching by radar sensor obtains flow velocity signal and the water level signal in monitoring range, and by signal processor, flow velocity signal and water level signal are processed, obtain the hydrographic data in monitoring range, without contacting under water, reduced the loss to monitoring device, and volume is small and exquisite, easy for installation, cost depletions and cost of human resources have been reduced, and use radar sensor to monitor, reduced external environment factor to the impact of measuring, improved the measurement precision of monitoring device, promoted the management intensity of Flood Disaster Management System.

Accompanying drawing explanation

In order to be illustrated more clearly in the embodiment of the present invention or technical scheme of the prior art, to the accompanying drawing of required use in embodiment or description of the Prior Art be briefly described below, apparently, accompanying drawing in the following describes is only some embodiments of the present invention, for those of ordinary skills, do not paying under the prerequisite of creative work, can also obtain according to these accompanying drawings other accompanying drawing.

Fig. 1 is the structural representation of a kind of Flood Disaster Management System of providing of the utility model embodiment;

Fig. 2 is the structural representation of a kind of flood monitoring device of providing of the utility model embodiment;

Fig. 3 is the structural representation of the another kind of flood monitoring device that provides of the utility model embodiment;

Fig. 4 is the structural representation of a kind of background monitoring platform of providing of the utility model embodiment.

Embodiment

Below in conjunction with the accompanying drawing in the utility model embodiment, the technical scheme in the utility model embodiment is clearly and completely described, obviously, described embodiment is only the utility model part embodiment, rather than whole embodiment.Based on the embodiment in the utility model, those of ordinary skills are not making the every other embodiment obtaining under creative work prerequisite, all belong to the scope of the utility model protection.

In the utility model embodiment, flood monitoring device can be for signals such as the water level within the scope of surveillance and monitoring, flow velocitys, and processes by signal the hydrographic data obtaining in monitoring range, for example: waterlevel data, flow speed data etc.Flood monitoring device is preferably applied in Flood Disaster Management System, and the water level in monitoring range and flow velocity are monitored.Flood monitoring device in the utility model embodiment can be monitored or the Nei Ge network of rivers, city is monitored the multiple place of waterlogging in city, for example: each freeing port in low lying areas, earth's surface, grade separation bridge opening and underground pipe network is monitored, river, incity and reservoir are monitored etc.

Refer to Fig. 1, for the utility model embodiment provides a kind of structural representation of Flood Disaster Management System.As shown in Figure 1, described Flood Disaster Management System comprises: flood monitoring device 1 and background monitoring platform 2.

Flood monitoring device 1, is connected with background monitoring platform 2;

In specific implementation, the signals such as water level within the scope of described flood monitoring device 1 surveillance and monitoring, flow, and by signal, process the hydrographic data obtaining in monitoring range, for example: waterlevel data, flow speed data etc.Described flood monitoring device 1 sends to described background monitoring platform 2 by all hydrographic datas that gather.

Background monitoring platform 2, is connected with described flood monitoring device 1;

In specific implementation, described background monitoring platform 2 receives the hydrographic data that described flood monitoring device 1 sends, hydrographic data described in output display.

Below in conjunction with accompanying drawing 2 and accompanying drawing 3, the flood monitoring device in above-mentioned Flood Disaster Management System is described in detail.

Please also refer to Fig. 2, described flood monitoring device 1 comprises: radar sensor 11, signal processor 12 and communicator 13, wherein, described radar sensor comprises the first radar sensor 111 and the second radar sensor 112, and described signal processor 12 comprises first signal processor 121 and secondary signal processor 122.

Radar sensor 11, is connected with described signal processor 12;

The radar beam of described radar sensor 11 covers monitoring range, described radar sensor 11 obtains flow velocity signal and the water level signal in described monitoring range by the radar beam reflecting, and described flow velocity signal and water level signal are sent to described signal processor 12.In specific implementation, described the first radar sensor 111 is connected with described first signal processor 121, and described the first radar sensor 111 obtains the flow velocity signal in described monitoring range, and described flow velocity signal is sent to described first signal processor 121; Described the second radar sensor 112 is connected with described secondary signal processor 122, and described the second radar sensor 112 obtains the water level signal in described monitoring range, and described flow velocity signal is sent to described secondary signal processor 122.

Signal processor 12, is connected with described communicator 13 with described radar sensor 11 respectively;

Described signal processor 12 receives flow velocity signal and the water level signal that described radar sensor 11 sends, described flow velocity signal and water level signal are carried out to filtering processing and digital signal processing, obtain the hydrographic data in the monitoring range that described radar sensor 11 monitors, described hydrographic data comprises flow speed data and waterlevel data etc., and described signal processor sends to described communicator 13 by the described hydrographic data obtaining.In specific implementation, described first signal processor 121 receives the flow velocity signal that described the first radar sensor 111 sends, and described flow velocity signal is carried out to filtering processing and digital signal processing, obtains flow speed data; Described secondary signal processor 122 receives the water level signal that described the second radar sensor 112 sends, and described water level signal is carried out to filtering processing and digital signal processing, obtains waterlevel data.Described first signal processor 121 is connected with described communicator 13 respectively with described secondary signal processor 122, described first signal processor 121 sends to described communicator 13 by described flow speed data, and described secondary signal processor 122 sends to described communicator 13 by described waterlevel data.

Communicator 13, is connected with described background monitoring platform 2 with described signal processor 12 respectively;

In the described monitoring range that described communicator 13 obtains described signal processor 12, the hydrographic data of water is sent to described background monitoring platform 2.In specific implementation, the waterlevel data that the flow speed data that described communicator 13 sends described first signal processor 121 and described secondary signal processor 122 send gathers, and the hydrographic data after gathering is sent to described background monitoring platform 2.

Please also refer to Fig. 3, described flood monitoring device 1 comprises the radar sensor 11 shown in Fig. 2, signal processor 12 and communicator 13, also comprises again: radar flowmeter 14, radar water-level gauge 15, accumulator 16 and solar panel 17.

Described radar flowmeter 14 has encapsulated described the first radar sensor 111 and described first signal processor 121, described radar water-level gauge 15 has encapsulated described the second radar sensor 112 and described secondary signal processor 122, and described radar flowmeter 14 is connected with described communicator 13 respectively with described radar water-level gauge 15;

Described radar flowmeter 14 obtains the flow velocity signal in described monitoring range, and described flow velocity signal is carried out to filtering processing and digital signal processing, obtains flow speed data; Described radar water-level gauge 15 obtains the water level signal in described monitoring range, and described water level signal is carried out to filtering processing and digital signal processing, obtains waterlevel data.Described radar flowmeter 14 sends to described communicator 13 by described flow speed data, and described radar water-level gauge 15 sends to described communicator 13 by described waterlevel data.

Accumulator 16, is connected with described radar flowmeter 14, described radar water-level gauge 15 and described communicator 13 respectively, and described accumulator 16 provides working power for described radar flowmeter 14, described radar water-level gauge 15 and described communicator 13.

Solar panel 17, is connected with described radar flowmeter 14, described radar water-level gauge 15 and described communicator 13 respectively, and described solar panel 17 provides working power for described radar flowmeter 14, described radar water-level gauge 15 and described communicator 13; Or when electric weight in described accumulator 16 is not enough, described solar panel 17 can provide Emergency Power for described radar flowmeter 14 and described radar water-level gauge 15, guarantees the normal work of described radar flowmeter 14 and described radar water-level gauge 15.

Below in conjunction with accompanying drawing 4, the background monitoring platform in above-mentioned Flood Disaster Management System is described in detail.

Please also refer to Fig. 4, described background monitoring platform 2 comprises display 21.

Display 21, is connected with described flood monitoring device 1;

Described display 21 receives the hydrographic data that the described communicator 13 in described flood monitoring device 1 sends, and described hydrographic data is carried out to output display, and monitor staff can monitor in real time according to the hydrographic data showing in described display 21.

In the utility model embodiment, the radar beam of launching by radar sensor obtains flow velocity signal and the water level signal in monitoring range, and by signal processor, flow velocity signal and water level signal are processed, obtain the hydrographic data in monitoring range, without contacting under water, reduced the loss to monitoring device, reduced cost depletions, and use radar sensor to monitor, reduced external environment factor to the impact of measuring, improve the measurement precision of monitoring device, promoted the management intensity of Flood Disaster Management System.

Above disclosed is only the utility model preferred embodiment, certainly can not limit with this interest field of the utility model, one of ordinary skill in the art will appreciate that all or part of flow process that realizes above-described embodiment, and the equivalent variations of doing according to the utility model claim, still belong to the scope that utility model contains.

Claims (8)

1. a flood monitoring device, is applied to Flood Disaster Management System, and described Flood Disaster Management System comprises background monitoring platform, it is characterized in that, described device comprises: radar sensor, signal processor and communicator, wherein,

The radar beam of described radar sensor covers monitoring range, and described radar sensor obtains flow velocity signal and the water level signal in described monitoring range by the radar beam reflecting;

Described signal processor is connected with described radar sensor, flow velocity signal and water level signal in the described monitoring range that described signal processor obtains described radar sensor are carried out filtering processing and digital signal processing, obtain the hydrographic data in described monitoring range;

Described communicator is connected with described background monitoring platform with described signal processor respectively, and the hydrographic data in the described monitoring range that described communicator obtains described signal processor is sent to described background monitoring platform.

2. device according to claim 1, is characterized in that, described radar sensor comprises the first radar sensor and the second radar sensor, and described signal processor comprises first signal processor and secondary signal processor, wherein,

Described the first radar sensor is connected with described first signal processor, and described the second radar sensor is connected with described secondary signal processor, and described first signal processor is connected with described communicator respectively with described secondary signal processor.

3. device according to claim 2, it is characterized in that, described the first radar sensor obtains the flow velocity signal in described monitoring range, and the flow velocity signal in the described monitoring range that described first signal processor obtains described the first radar sensor carries out filtering processing and digital signal processing;

Described the second radar sensor obtains the water level signal in described monitoring range, and the water level signal in the described monitoring range that described secondary signal processor obtains described the second radar sensor is carried out filtering processing and digital signal processing.

4. according to the device described in claim 2 or 3, it is characterized in that, described device also comprises radar flowmeter and radar water-level gauge, wherein,

Described radar flowmeter has encapsulated described the first radar sensor and described first signal processor, described radar water-level gauge has encapsulated described the second radar sensor and described secondary signal processor, and described radar flowmeter is connected with described communicator respectively with described radar water-level gauge.

5. device according to claim 4, is characterized in that, described device also comprises accumulator, and described accumulator is connected with described communicator with described radar flowmeter, described radar water-level gauge respectively.

6. device according to claim 4, is characterized in that, described device also comprises solar panel, and described solar panel is connected with described communicator with described radar flowmeter, described radar water-level gauge respectively.

7. a Flood Disaster Management System, comprises background monitoring platform, it is characterized in that, also comprises: at least one flood monitoring device as described in power 1-6 any one; Wherein,

Described background monitoring platform is connected with described flood monitoring device, and described background monitoring platform receives and export the hydrographic data in the described monitoring range that described flood monitoring device sends.

8. system according to claim 7, is characterized in that, described background monitoring platform comprises:

With the display that described flood monitoring device is connected, described display shows the hydrographic data in the described monitoring range that described flood monitoring device sends.

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