CN217818734U - Husky monitoring integrated platform of water - Google Patents

Abstract

The utility model provides a water and sand monitoring integrated platform, which comprises a first power supply platform and a second power supply platform; the first power supply platform is connected with a first storage battery, and the second power supply platform is connected with a second storage battery; the first storage battery is connected with a signal collecting device, and the signal collecting device is connected with a terminal machine; the first storage battery is connected with a rapid flow meter, and the rapid flow meter is connected with the terminal; the terminal is connected with the second storage battery; the online flow measuring system V-ADCP needs to be fixed under the water of the buoy ship, a flow field is not disturbed, a hole is excavated in the buoy ship, a supporting cylinder is welded with the outlet of the buoy, a flow measuring instrument supporting rod extends into the water through the supporting cylinder, a positioning disc is used for positioning the flow measuring instrument supporting rod, and a supporting cover is buckled with the supporting cylinder, so that the installation of the rapid flow measuring instrument is completed.

Description

Integrated platform for monitoring water and sand

Technical Field

The utility model relates to a hydrology monitoring field especially relates to a sand and water monitoring integration platform.

Background

An Acoustic Doppler Current Profiler (ADCP) is an advanced flow rate measuring instrument, and measures the flow rate by using the Doppler shift generated by the Acoustic pulse emitted by an Acoustic transducer in suspended substances moving with water flow.

Unlike conventional rotor-type flow meters, the ADCP flow rate measurement point is not at the ADCP location, but rather measures the flow rate at many points within a certain range, i.e., one ADCP is equivalent to a plurality of conventional flow meters simultaneously. The method has the outstanding characteristics of capability of measuring the three-dimensional flow velocity and the flow direction of different water layers, no disturbance of the flow field, capability of continuous measurement, short duration of flow measurement, capability of improving the representativeness of the measured flow, lightening the test intensity and improving the working efficiency. Due to the advantages, the existing navigation ADCP is introduced and put into production and use in the Yangtze river basin in large quantity. The sailing type ADCP has high sampling rate and the defects that the hydrological survey ship needs to be used for crossing, the survey time is long, and the real-time effect cannot be achieved. At present, the sand content and the grain composition of suspended load are sampled by adopting a horizontal sampler, and the sampler needs to be positioned by a hydrological measuring ship and placed to a specified water depth. After water sample collection, 3-5 days of precipitation is needed, the water sample is concentrated and then taken back to a laboratory to be dried by an oven, and then an electronic balance is used for weighing to calculate the sand content.

As the ship body is provided with the current meter and the sand meter, the wiring of the ship body is very disordered, thereby influencing the data acquisition and the equipment maintenance.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to above-mentioned prior art not enough, provide a water and sand monitoring integrated platform, the installation is reasonable, is convenient for realize the maintenance of equipment.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a water and sand monitoring integrated platform, which comprises a first power supply platform and a second power supply platform; the first power supply platform is connected with a first storage battery, and the second power supply platform is connected with a second storage battery;

the first storage battery is connected with a signal collecting device, and the signal collecting device is connected with a terminal machine;

the first storage battery is connected with a rapid current measuring instrument, and the rapid current measuring instrument is connected with the terminal;

the terminal is connected with the second storage battery.

Further, the first power supply platform and the second power supply platform both comprise a solar cell panel and a support frame, and the solar cell panel and the support frame are installed mutually.

Further, the first storage battery and the second storage battery are both installed in the radio box.

Further, the signal collecting device and the terminal machine are both installed in a control box.

Furthermore, the quick current meter is installed at the bottom of the current meter supporting rod, and the current meter supporting rod extends into the supporting cylinder.

Furthermore, one end of the supporting cylinder is welded with the ship body, and a supporting cover covers the surface of the supporting cylinder.

Further, the supporting cover is sleeved with the flow meter supporting rod.

Furthermore, a positioning disc is arranged between the rapid flow meter and the supporting cover.

Furthermore, the positioning disc is sleeved on the flow meter supporting rod.

The utility model has the advantages that:

the solar cell panel can supply power to the whole platform so as to realize real-time water and sand supervision;

the rapid flow meter penetrates through the supporting cylinder and extends into the water through the flow meter supporting rod, so that the data acquisition of the watershed is facilitated in the advancing process of the ship body;

in addition, the positioning disc is sleeved on the supporting rod of the flow meter, so that the positioning in the supporting cylinder of the flow meter is facilitated, and the stable installation of the flow meter is facilitated.

Drawings

Fig. 1 is a schematic structural diagram of a water and sand monitoring integrated platform of the present invention;

FIG. 2 is a block diagram of a water and sand monitoring integrated platform;

fig. 3 is a schematic structural diagram of a support rod of the flow meter.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention will be further described in detail with reference to the accompanying drawings. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

Referring to fig. 1 and 2, a water and sand monitoring integrated platform includes a first power supply platform 101 and a second power supply platform 102; the first power supply platform 101 is connected with a first storage battery 201, and the second power supply platform 102 is connected with a second storage battery 202;

the first storage battery 201 is connected with a signal collecting device 3, and the signal collecting device 3 is connected with a terminal 4;

the first storage battery 201 is connected with a rapid current measuring instrument 5, and the rapid current measuring instrument 5 is connected with the terminal 4;

the terminal 4 is connected to the second battery 202.

The first power supply platform 101 and the second power supply platform 102 both include a solar panel 103 and a support frame 104, and the solar panel 103 and the support frame 104 are installed together.

In one possible implementation, the solar cell panel 103 and the support bracket 104 may be mounted by screws and screw holes.

In one possible implementation, the solar panel is connected to the battery through a solar charging controller.

In a possible implementation, the second power supply platform 102 supplies power to the terminal 4;

the first power supply platform 102 supplies power to the signal collection device 3 and the rapid current meter 5 respectively.

The first battery 201 and the second battery 202 are both mounted in the radio frequency box 2.

The signal collecting device 3 and the terminal 4 are both installed in a control box 6.

In a possible implementation, a compass 601 is also mounted on one side of the control box 6 for positioning and orientation, and the compass 601 also sends signals to the signal collection device 3.

In a possible implementation, the signal collection means 3, of type YAC2018H, are used to collect and transmit information.

Referring to fig. 3, the rapid flow meter 5 is installed at the bottom of a flow meter support rod 501, and the flow meter support rod 501 extends into a support cylinder 502.

One end of the supporting cylinder 502 is welded with the ship body, and the surface of the supporting cylinder 502 is covered with a supporting cover 503.

The supporting cover 503 is sleeved with the flow meter supporting rod 501.

A positioning disc 504 is arranged between the rapid flow meter 5 and the supporting cover 503.

The positioning plate 504 is sleeved on the flow meter supporting rod 501.

In a possible implementation manner, the supporting cylinder 502 is communicated with the ship body, the flow meter supporting rod 501 extends into the flow area through the supporting cylinder 502, and the rapid flow meter 5 is installed at the bottom of the flow meter supporting rod 501, namely, the rapid flow meter 5 can measure the hydrological data of the flow area.

In a possible implementation mode, the diameter of the end, away from the ship body, of the supporting cylinder 502 is larger than that of the end, connected with the ship body, of the supporting cylinder, and the diameter of the positioning disc 504 is consistent with that of the end, connected with the ship body, of the supporting cylinder 502, so that when the positioning disc 504 extends into the supporting cylinder 502, the positioning disc is clamped by the bottom end of the supporting cylinder 502, and the flow meter supporting rod 501 is positioned.

In a possible implementation manner, the supporting cover 503 is fastened to the supporting cylinder 502, screw holes are formed on one side of the supporting cover 503 and one side of the supporting cylinder 502, and screws 507 are inserted through the screw holes to fix the supporting cover 503 to the supporting cylinder 502.

Referring again to fig. 1, the integrated platform further comprises a sand measuring instrument, wherein the sand measuring instrument comprises a sand measuring sensor 7, the sand measuring sensor 7 is connected with a data acquisition system of TES-91, data is acquired through the TES-91 and transmitted to a data center, the data acquisition of the TES-91 is installed in the box 8, and both the data acquisition of the TES-91 and the sand measuring sensor can be powered by the solar panel 9.

The above-mentioned embodiments only express the embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be defined by the appended claims.

Claims (9)

1. The utility model provides a sand and water monitoring integration platform which characterized in that: comprises a first power supply platform (101) and a second power supply platform (102); the first power supply platform (101) is connected with a first storage battery (201), and the second power supply platform (102) is connected with a second storage battery (202);

the first storage battery (201) is connected with a signal collecting device (3), and the signal collecting device (3) is connected with a terminal (4);

the first storage battery (201) is connected with a rapid current measuring instrument (5), and the rapid current measuring instrument (5) is connected with the terminal (4);

the terminal (4) is connected to the second battery (202).

2. The integrated water and sand monitoring platform according to claim 1, wherein: the first power supply platform (101) and the second power supply platform (102) both comprise a solar cell panel (103) and a support frame (104), and the solar cell panel (103) and the support frame (104) are installed.

3. The integrated water and sand monitoring platform according to claim 2, wherein: the first accumulator cell (201) and the second accumulator cell (202) are both mounted in an electronic frequency box (2).

4. The integrated water and sand monitoring platform according to claim 3, wherein: the signal collecting device (3) and the terminal (4) are both arranged in a control box (6).

5. The integrated water and sand monitoring platform according to claim 4, wherein: the rapid flow meter (5) is arranged at the bottom of a flow meter supporting rod (501), and the flow meter supporting rod (501) extends into the supporting cylinder (502).

6. The integrated water and sand monitoring platform according to claim 5, wherein: one end of the supporting cylinder (502) is welded with the ship body, and the surface of the supporting cylinder (502) is covered with a supporting cover (503).

7. The integrated water and sand monitoring platform according to claim 6, wherein: the supporting cover (503) is sleeved with the flow meter supporting rod (501).

8. The integrated water and sand monitoring platform according to claim 7, wherein: and a positioning disc (504) is arranged between the rapid flow meter (5) and the supporting cover (503).

9. The integrated water and sand monitoring platform according to claim 8, wherein: the positioning disc (504) is sleeved on the flow meter supporting rod (501).

Images