CN216847856U - Hydrology remote automatic monitoring system - Google Patents

Abstract

The utility model relates to the technical field of hydrological monitoring, and particularly discloses a hydrological remote automatic monitoring system which comprises a floating plate, wherein a mounting frame is arranged on the lower end surface of the floating plate, the mounting frame comprises a bottom plate connected with the floating plate, two vertical plates which are parallel to each other and are perpendicular to the bottom plate are arranged on the lower end surface of the bottom plate, a rotatable filter cover is arranged between the two vertical plates, a driving mechanism for driving the filter cover to rotate is arranged on the floating plate, the filter cover comprises a cylindrical filter screen, and circular plates are arranged at two ends of the filter screen; one of the two vertical plates is provided with a through connecting column, the connecting column penetrates through the circular plate adjacent to the connecting column and extends into the filter screen, the end part of the connecting column extending into the filter screen is connected with a mounting plate, and the mounting plate is provided with a flow velocity sensor and a flow sensor. According to the utility model, the sensor module is arranged in the filter screen, so that sundries such as aquatic weeds in water flow are prevented from being attached to the sensor module, and the stability of the sensor module in use is improved better.

Description

Hydrology remote automatic monitoring system

Technical Field

The utility model relates to the technical field of hydrological monitoring, in particular to a hydrological remote automatic monitoring system.

Background

The hydrological monitoring is used for monitoring rivers, lakes in real time, the monitoring content comprises flow, flow velocity and the like, the current hydrological monitoring system generally utilizes a flow sensor and a flow velocity sensor to monitor the flow velocity and the flow of water flow, but in actual use, impurities such as aquatic plants in the water flow are attached to the sensor (such as a propeller type current meter and an ultrasonic flowmeter), so that the sensor cannot work normally.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problems, the utility model is solved by the following technical scheme:

a hydrological remote automatic monitoring system comprises a floating plate, wherein a mounting frame is arranged on the lower end face of the floating plate, the mounting frame comprises a bottom plate connected with the floating plate, two vertical plates which are parallel to each other and perpendicular to the bottom plate are arranged on the lower end face of the bottom plate, a rotatable filter cover is arranged between the two vertical plates, a driving mechanism for driving the filter cover to rotate is arranged on the floating plate, the filter cover comprises a cylindrical filter screen, and circular plates are arranged at two ends of the filter screen; one of the two vertical plates is provided with a through connecting column, the connecting column penetrates through the circular plate adjacent to the connecting column and extends into the filter screen, the end part of the connecting column extending into the filter screen is connected with a mounting plate, and the mounting plate is provided with a flow velocity sensor and a flow sensor.

According to the utility model, the sensor module is arranged in the filter screen, so that sundries such as aquatic weeds in water flow are prevented from being attached to the sensor module, and the stability of the sensor module in use is improved better.

Preferably, actuating mechanism includes the rotation post, rotates the post and sets up on the lateral wall of the plectane far away from the spliced pole, and the riser is stretched out to the tip of spliced pole, and the tip that stretches out the riser on the spliced pole is equipped with first bevel gear, is equipped with the motor on the kickboard, and the kickboard is stretched out to the pivot of motor, and the tip that stretches out the kickboard in the motor shaft is equipped with the second bevel gear with first bevel gear engaged with.

According to the utility model, the driving of the filter screen can be better realized through the arrangement of the driving mechanism structure.

Preferably, a brush for brushing off the attachments on the filter screen is arranged between the two vertical plates.

In the utility model, through the arrangement of the brush, attachments which are difficult to throw off and are attached on the filter screen can be scraped.

Preferably, the brush comprises a brush plate, two end parts of the brush plate are connected with the vertical plate through bolts, and brush bristles abutted against the filter screen are arranged on the end face, close to the filter screen, of the brush plate.

According to the utility model, through the arrangement of the brush structure, not only can impurities on the filter screen be better brushed, but also the installation of the brush is more conveniently realized.

Preferably, the upper end surface of the floating plate is provided with a cover, and the cover is connected with the floating plate through bolts.

In the utility model, the arrangement of the outer cover can better realize the protection of the electric elements on the upper end surface of the floating plate

Preferably, the bottom plate and the lower end surface of the floating plate are connected through bolts.

In the utility model, the installation of the installation frame can be conveniently realized through the bolt connection between the bottom plate and the floating plate.

Drawings

Fig. 1 is a schematic structural diagram of a hydrological remote automatic monitoring system in embodiment 1.

Fig. 2 is a sectional view of the hydrological remote automatic monitoring system of fig. 1.

Fig. 3 is a schematic structural view of the mount according to embodiment 1.

Fig. 4 is a schematic diagram of the hydrological remote automatic monitoring system in embodiment 1.

Detailed Description

For a further understanding of the utility model, reference should be made to the following detailed description taken in conjunction with the accompanying drawings and examples. It is to be understood that the examples are illustrative of the utility model and not limiting.

Example 1

As shown in fig. 1 to 4, the present embodiment provides a hydrologic remote automatic monitoring system, which includes a floating plate 110, wherein a mounting rack is disposed on a lower end surface of the floating plate 110, the mounting rack includes a bottom plate 210 connected to the floating plate 110, and the bottom plate 210 is bolted to the lower end surface of the floating plate 110. The lower terminal surface of bottom plate 210 is equipped with two parallel and perpendicular to bottom plate 210 the riser 220 that sets up, be equipped with rotatable filter mantle 120 between two risers 220, be equipped with the actuating mechanism who is used for driving filter mantle 120 pivoted on the kickboard 110, actuating mechanism includes rotation post 290, rotation post 290 sets up on the lateral wall of the plectane 240 of keeping away from spliced pole 250, the riser 220 is stretched out to the tip of spliced pole 250, the tip that stretches out riser 220 on the spliced pole 250 is equipped with first 2100 bevel gear, be equipped with motor 2110 on the kickboard 110, the kickboard 110 is stretched out to the pivot of motor 2110, the tip that stretches out the kickboard 110 in the pivot of motor 2110 is equipped with second bevel gear 2120 with first bevel gear 2100 looks meshing. The filter cover 120 includes a filter screen 230 having a cylindrical shape, and both ends of the filter screen 230 are provided with circular plates 240; one of the two vertical plates 220 is provided with a connecting column 250, the connecting column 250 penetrates through a circular plate 240 adjacent to the connecting column and extends into the filter screen 230, the end part of the connecting column 250 extending into the filter screen 230 is connected with a mounting plate 260, the mounting plate 260 is provided with a sensor module, the sensor module comprises a flow velocity sensor 270 and a flow sensor 280, the floating plate is provided with a processing module connected with the sensor module, and the processing module is connected with a wireless communication module used for sending information; the sensor module detects the hydrological parameters and sends data to the processing module, the processing module is used for processing the data and sending the data to terminals such as a computer through the wireless communication module, and the floating plate is further provided with a storage battery 2130 used for supplying power to the motor, the control module, the sensor module and the wireless communication module. In order to protect the electrical components on the upper end of the floating plate 110, the upper end of the floating plate 110 is provided with a cover 130, and the cover 130 is connected to the floating plate 110 by bolts. In order to brush down the attachments attached to the filter screen 230, a brush for brushing down the attachments attached to the filter screen 230 is provided between the two vertical plates 220. The brush comprises a brush plate 310, two ends of the brush plate 310 are connected with the vertical plate 220 through bolts, and bristles 320 abutted against the filter screen 230 are arranged on the end face, close to the filter screen 230, of the brush plate 310.

When the automatic hydrological remote monitoring system in the embodiment is used, the floating plate 110 floats on the water surface, the sensor module detects hydrological parameters and sends data to the processing module, and the processing module is used for processing the data and sending the data to terminals such as a computer through the wireless communication module, so that the hydrological parameters can be remotely monitored. Through setting up the sensor module in filter screen 230, avoided debris such as pasture and water in the rivers to attach to the sensor module to the promotion of preferred sensor module stability when using. Due to the rotatable arrangement of the filter screen 230, sundries such as aquatic weeds are further prevented from being attached to the filter screen 230, so that the sensor module is prevented from being interfered by blockage of the filter screen 230, and the accuracy of the measurement data of the sensor module is improved.

Through the cooperation between the motor 2110, the first bevel gear 2100 and the second bevel gear 2120, the driving of the rotating column 290, that is, the driving of the filter screen 230, can be realized through the engagement between the second bevel gear 2120 and the first bevel gear 2100 on the rotating shaft of the motor 2110, so that the driving of the filter screen 230 is preferably realized.

The arrangement of the brush can scrape off the attachments which are difficult to throw off and are attached to the filter screen 230, so that the impurities in the water are further prevented from being attached to the filter screen 230. Through the arrangement of the brush structure, not only can the impurities on the filter screen 230 be better brushed down, but also the installation of the brush is more conveniently realized.

Among them, the protection of the electric elements such as the motor and the storage battery 2130 on the upper end surface of the floating plate 110 can be preferably realized by the arrangement of the cover 130.

The bolt connection between the bottom plate 210 and the floating plate 110 can facilitate the installation of the mounting frame.

In summary, the above-mentioned embodiments are only preferred embodiments of the present invention, and all equivalent changes and modifications made in the claims of the present invention should be covered by the claims of the present invention.

Claims (5)

1. The utility model provides a hydrology remote automatic monitoring system which characterized in that: the floating plate type filter screen comprises a floating plate (110), wherein a mounting frame is arranged on the lower end face of the floating plate (110), the mounting frame comprises a bottom plate (210) connected with the floating plate (110), two vertical plates (220) which are parallel to each other and perpendicular to the bottom plate (210) are arranged on the lower end face of the bottom plate (210), a rotatable filter cover (120) is arranged between the two vertical plates (220), a driving mechanism used for driving the filter cover (120) to rotate is arranged on the floating plate (110), the filter cover (120) comprises a cylindrical filter screen (230), and circular plates (240) are arranged at two ends of the filter screen (230); one vertical plate (220) of the two vertical plates (220) is provided with a through connecting column (250), the connecting column (250) penetrates through the circular plate (240) adjacent to the connecting column and extends into the filter screen (230), the end part of the connecting column (250) extending into the filter screen (230) is connected with a mounting plate (260), and the mounting plate (260) is provided with a flow velocity sensor (270) and a flow sensor (280); the driving mechanism comprises a rotating column (290), the rotating column (290) is arranged on the outer side wall of a circular plate (240) far away from a connecting column (250), a vertical plate (220) extends out of the end part of the connecting column (250), a first bevel gear (2100) is arranged at the end part of the connecting column (250) extending out of the vertical plate (220), a motor (2110) is arranged on the floating plate (110), a rotating shaft of the motor (2110) extends out of the floating plate (110), and a second bevel gear (2120) meshed with the first bevel gear (2100) is arranged at the end part of the rotating shaft of the motor (2110) extending out of the floating plate (110).

2. The hydrological remote automatic monitoring system according to claim 1, characterized in that: a brush used for brushing down the attachments on the filter screen (230) is arranged between the two vertical plates (220).

3. The hydrological remote automatic monitoring system according to claim 2, characterized in that: the brush comprises a brush plate (310), two end parts of the brush plate (310) are connected with the vertical plate (220) through bolts, and brush bristles (320) abutted against the filter screen (230) are arranged on the end face, close to the filter screen (230), of the brush plate (310).

4. The hydrological remote automatic monitoring system according to claim 1, characterized in that: an outer cover (130) is arranged on the upper end face of the floating plate (110), and the outer cover (130) is connected with the floating plate (110) through bolts.

5. The hydrological remote automatic monitoring system according to claim 1, characterized in that: the bottom plate (210) is connected with the lower end surface of the floating plate (110) through bolts.

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