CN216387036U - Novel water quality monitoring's remote sensing appearance - Google Patents

Abstract

The utility model discloses a novel remote sensing instrument for water quality monitoring, which comprises a casing, the outer wall of the casing is provided with a buoyancy plate, the top outer wall of the casing is provided with a maintenance door, and the inner wall of the casing is fixedly connected with a buoyancy plate. a mounting plate, the mounting plate and the inner wall of the housing form a cavity, the top outer wall of the mounting plate is provided with a wireless communication device, the top outer wall of the mounting plate is provided with a GPS positioning device, and the bottom outer wall of the mounting plate is provided with a wireless communication device There is a detection device, the bottom outer wall of the casing is provided with a hole 1, the inner wall of the hole 1 is inserted with a hydraulic rod, and the hydraulic rod is fixedly connected with the top inner wall of the casing. In the utility model, the water inlet pipe is arranged, the hydraulic rod is used to drive the water inlet pipe to the required depth through the telescopic water pipe, the valve is opened, and the pressure difference in the water is used to make the water flow into the cavity through the water inlet pipe and the telescopic water pipe, and the water quality is detected by the detection device. Monitoring, making the data more convincing.

Description

A new type of remote sensing instrument for water quality monitoring

technical field

The utility model relates to the technical field of water quality monitoring, in particular to a novel remote sensing instrument for water quality monitoring.

Background technique

Water quality monitoring is the process of monitoring and measuring the types of pollutants in the water body, the concentrations and changing trends of various pollutants, and evaluating the water quality. The monitoring range is very wide, including unpolluted and polluted natural water (river, river, lake, sea and groundwater) and various industrial drainage, etc. The main monitoring items can be divided into two categories: one is Comprehensive indicators reflecting water quality conditions, such as temperature, chromaticity, turbidity, pH value, electrical conductivity, suspended solids, dissolved oxygen, chemical oxygen demand and biochemical oxygen demand, etc.; the other category is some toxic substances, such as phenol, Cyanide, arsenic, lead, chromium, cadmium, mercury and organic pesticides, etc., in order to objectively evaluate the water quality of rivers and oceans, in addition to the above monitoring items, sometimes it is necessary to measure the flow rate and flow.

However, in the prior art, the water quality of the water at different depths of the river is different. However, most of the remote sensing instruments used for water quality monitoring can only monitor the water at the same depth in the same area, and cannot monitor the specific depth in detail. monitoring of water, resulting in unconvincing data.

Utility model content

The purpose of the present utility model is to provide a new type of remote sensing instrument for water quality monitoring, so as to solve the problems raised in the above background technology.

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

A new type of remote sensing instrument for water quality monitoring includes a casing, the outer wall of the casing is provided with a buoyancy plate, the top outer wall of the casing is provided with a maintenance door, the inner wall of the casing is fixedly connected with a mounting plate, and the The mounting plate and the inner wall of the housing form a cavity, the top outer wall of the mounting plate is provided with a wireless communication device, the top outer wall of the mounting plate is provided with a GPS positioning device, and the bottom outer wall of the mounting plate is provided with a detection device, so The bottom outer wall of the casing is provided with a hole 1, the inner wall of the hole 1 is inserted with a hydraulic rod, the hydraulic rod is fixedly connected with the top inner wall of the casing, the hydraulic rod is inserted with the mounting plate, and the casing The bottom outer wall of the body is provided with a second hole, the inner wall of the second hole is inserted with a telescopic water pipe, one end of the telescopic water pipe is inserted with a water inlet pipe, and the outer wall of the water inlet pipe is provided with a number of water inlet holes. The inner wall of the water pipe is provided with a valve, one end of the piston rod of the hydraulic rod is fixedly connected with a connecting block, the connecting block is fixedly connected with the outer wall of the telescopic water pipe, and the outer wall of the casing is provided with a power mechanism.

Further, the power mechanism includes a second mounting block, the second mounting block is fixedly connected to the outer wall of the housing, one side outer wall of the second mounting block is provided with a hole three, and the inner wall of the third hole is provided with a second motor, so One end of the output shaft of the second motor is fixedly connected with a transmission rod, one end of the transmission rod is fixedly connected with a power paddle, and the second motor is electrically connected with the wireless communication device.

Further, a first mounting block is fixedly connected to the outer wall of the housing, the first mounting block is symmetrically distributed, and the two mounting blocks are at a 90-degree angle between the first mounting block and the second mounting block, and one side of the mounting block one is The outer wall is provided with a hole 4, the inner wall of the hole 4 is fixedly connected with a motor 1, one end of the output shaft of the motor 1 is fixedly connected with a guide plate, and the motor 1 is electrically connected with the wireless communication device.

Further, the top and bottom outer walls of the guide plate are both triangular-shaped.

Further, the bottom outer wall of the housing is fixedly connected with a limit slide rod, the outer wall of the limit slide rod is sleeved with a limit slide sleeve, and the limit slide sleeve is fixedly connected with the outer wall of the telescopic water pipe.

Further, a filter plate is fixedly connected to the inner wall of the telescopic water pipe.

Further, the bottom outer wall of the buoyancy plate is fixedly connected with diverting knives, and the diverting knives are symmetrically distributed.

Further, a liquid level gauge is arranged inside the cavity, the liquid level gauge is fixedly connected with the mounting plate, and the liquid level gauge and the valve are electrically connected.

Compared with the prior art, the beneficial effects of the present utility model are:

1. The utility model uses the hydraulic rod to drive the water inlet pipe to the required depth through the telescopic water pipe by setting the water inlet pipe, opens the valve, and uses the pressure difference in the water to make the water flow into the cavity through the water inlet pipe and the telescopic water pipe, and passes through the detection device. Monitoring water quality to make the data more convincing;

2. The utility model uses the power mechanism to move the casing in the river water by setting the guide plate, and then brings the casing to the area to be detected, uses the motor to control the angle of the guide plate, and then uses the relationship between the water flow and the guide plate. The resistance generated between them is used to control the direction of the movement of the casing, and the casing can move quickly and accurately to the area that needs to be monitored.

Description of drawings

Fig. 1 is the overall structure schematic diagram that the utility model proposes;

2 is a schematic structural diagram of the liquid level gauge proposed by the utility model;

FIG. 3 is a schematic structural diagram of the filter plate proposed by the utility model.

In the picture: 1. buoyancy plate; 2. shell; 3. maintenance door; 4. shunt knife; 5. mounting block 1; 6. motor 1; 7. guide plate; 8. limit slider; 9. limit Sliding sleeve; 10. Water inlet pipe; 11. Connecting block; 12. Hydraulic rod; 13. Mounting block 2; 14. Motor 2; 15. Transmission rod; 16. Power paddle; 17. Mounting plate; 18. GPS positioning device; 19, wireless communication device; 20, liquid level gauge; 21, detection device; 22, telescopic water pipe; 23, water inlet hole; 24, valve; 25, filter plate.

Detailed ways

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. Obviously, the described embodiments are only a part of the embodiments of the present utility model, rather than all the implementations. example. Based on the embodiments of the present invention, all other embodiments obtained by those of ordinary skill in the art without creative work fall within the protection scope of the present invention.

Please refer to FIGS. 1 to 3 , in an embodiment of the present invention, a novel remote sensing instrument for water quality monitoring includes a housing 2 , the outer wall of the housing 2 is provided with a buoyancy plate 1 , and the top outer wall of the housing 2 is provided with a maintenance door 3 , the inner wall of the housing 2 is fixedly connected with a mounting plate 17, the mounting plate 17 and the inner wall of the housing 2 form a cavity, the top outer wall of the mounting plate 17 is provided with a wireless communication device 19, and the top outer wall of the mounting plate 17 is provided with a GPS positioning device 18. The bottom outer wall of the mounting plate 17 is provided with a detection device 21, the bottom outer wall of the casing 2 is provided with a hole 1, the inner wall of the hole 1 is inserted with a hydraulic rod 12, and the hydraulic rod 12 is fixedly connected with the top inner wall of the casing 2. The rod 12 is inserted into the mounting plate 17, the bottom outer wall of the housing 2 is provided with a hole 2, the inner wall of the hole 2 is inserted with a telescopic water pipe 22, and one end of the telescopic water pipe 22 is inserted with a water inlet pipe 10, and the outer wall of the water inlet pipe 10 is provided with There are several water inlet holes 23, the inner wall of the water inlet pipe 10 is provided with a valve 24, one end of the piston rod of the hydraulic rod 12 is fixedly connected with a connecting block 11, and the connecting block 11 is fixedly connected with the outer wall of the telescopic water pipe 22, and the outer wall of the housing 2 is provided with There is a power mechanism, the hydraulic rod 12 is used to drive the water inlet pipe 10 to the required depth through the telescopic water pipe 22, the valve 24 is opened, and the pressure difference in the water is used to make the water flow into the cavity through the water inlet pipe 10 and the telescopic water pipe 22, and the detection device Monitoring water quality makes the data more convincing.

Further, the power mechanism includes a second mounting block 13, the second mounting block 13 is fixedly connected with the outer wall of the housing 2, one side outer wall of the second mounting block 13 is provided with a hole three, and the inner wall of the third hole is provided with a second motor 14, and the second motor One end of the output shaft is fixedly connected with a transmission rod 15 , and one end of the transmission rod 15 is fixedly connected with a power paddle 16 .

Further, the outer wall of the housing 2 is fixedly connected with a mounting block one 5, the mounting block one 5 is symmetrically distributed, and the two mounting blocks one 5 are at ninety degrees with the mounting block two 13, and one side of the outer wall of the mounting block one 5 is opened. There is a hole four, the inner wall of the hole four is fixedly connected with a motor one 6, one end of the output shaft of the motor one 6 is fixedly connected with a guide plate 7, the motor one 6 is electrically connected with the wireless communication device 19, and the guide plate 7 controls the housing 2 direction of movement.

Further, the top and bottom outer walls of the guide plate 7 are both triangular, and the triangular shape can reduce the resistance between the guide plate 7 and the water flow.

Further, the bottom outer wall of the housing 2 is fixedly connected with the limit slide bar 8, the outer wall of the limit slide bar 8 is sleeved with the limit slide sleeve 9, and the limit slide sleeve 9 is fixedly connected with the outer wall of the telescopic water pipe 22, using the limit slide bar. 8 and the limiting sliding sleeve 9 have a limiting effect on the movement of the telescopic water pipe 22 .

Further, a filter plate 25 is fixedly connected to the inner wall of the telescopic water pipe 22 , and the filter plate 25 is used to filter the water flowing into the telescopic water pipe 22 .

Further, the bottom outer wall of the buoyancy plate 1 is fixedly connected with diverting knives 4, and the diverting knives 4 are symmetrically distributed.

Further, a liquid level gauge 20 is arranged inside the cavity, the liquid level gauge 20 is fixedly connected with the mounting plate 17 , the liquid level gauge 20 is electrically connected with the valve 24 , and the liquid level gauge 20 is used to detect the water level in the cavity.

The working principle of the utility model is:

Put the shell 2 into the river, use the buoyancy plate 1 to make the shell 2 play a supporting effect, use the power mechanism and the guide plate 7 to move the shell 2 to the area that needs to be monitored, the hydraulic rod 12 passes through the connecting block 11 and The telescopic water pipe 22 moves the water inlet pipe 10 to the required depth, opens the valve 24 in the water inlet pipe 10, and uses the pressure difference in the water to make the water of this depth enter the cavity through the water inlet hole 23 and the telescopic water pipe 22, When the liquid level gauge 20 detects that the water level in the cavity reaches a specified value, the valve 24 is closed, and under the action of the buoyancy plate 1, the shell 2 will not sink too much, and the water in the cavity is detected by the detection device 21. , the detected data is transmitted through the wireless communication device 19, and made into a spectrogram, which is viewed by professionals. After the detection is completed, the hydraulic rod 12 will be used to drive the telescopic water pipe 22 to rise, the valve 24 will be opened, and part of the water will be discharged. Then, the transmission mechanism and the guide plate 7 are used to move the housing 2 to the shore, and the worker picks up the housing 2 and prepares to detect the next area.

Although the present invention has been described in detail with reference to the foregoing embodiments, for those skilled in the art, it is still possible to modify the technical solutions described in the foregoing embodiments, or perform equivalent replacements for some of the technical features. Within the spirit and principle of the present utility model, any modifications, equivalent replacements, improvements, etc. made shall be included within the protection scope of the present utility model.

Claims (8)

1. The utility model provides a novel water quality monitoring's remote sensing appearance, includes casing (2), its characterized in that, the outer wall of casing (2) is provided with buoyancy board (1), the top outer wall of casing (2) is provided with maintenance door (3), the inner wall fixedly connected with mounting panel (17) of casing (2), mounting panel (17) and the inner wall of casing (2) form the cavity, the top outer wall of mounting panel (17) is provided with wireless communication device (19), the top outer wall of mounting panel (17) is provided with GPS positioner (18), the bottom outer wall of mounting panel (17) is provided with detection device (21), the bottom outer wall of casing (2) is seted up porosely one, the inner wall of porosely one is pegged graft and is had hydraulic stem (12), hydraulic stem (12) and the top inner wall fixed connection of casing (2), hydraulic stem (12) are pegged graft with mounting panel (17), the bottom outer wall of casing (2) is seted up porose two, the inner wall in hole two is pegged graft and is had flexible water pipe (22), the one end of flexible water pipe (22) is pegged graft and is had inlet tube (10), the outer wall of inlet tube (10) is provided with a plurality of inlet opening (23), the inner wall of inlet tube (10) is provided with valve (24), piston rod one end fixedly connected with connecting block (11) of hydraulic stem (12), the outer wall fixed connection of connecting block (11) and flexible water pipe (22), the outer wall of casing (2) is provided with power unit.

2. The novel water quality monitoring remote sensing instrument according to claim 1, wherein the power mechanism comprises a second mounting block (13), the second mounting block (13) is fixedly connected with the outer wall of the shell (2), a third hole is formed in the outer wall of one side of the second mounting block (13), a second motor (14) is arranged on the inner wall of the third hole, one end of an output shaft of the second motor (14) is fixedly connected with a transmission rod (15), one end of the transmission rod (15) is fixedly connected with a power paddle (16), and the second motor (14) is electrically connected with the wireless communication device (19).

3. The novel water quality monitoring remote sensing instrument according to claim 2, wherein a first mounting block (5) is fixedly connected to the outer wall of the casing (2), the first mounting blocks (5) are symmetrically distributed, two first mounting blocks (5) and a second mounting block (13) are ninety degrees therebetween, a fourth hole is formed in the outer wall of one side of the first mounting block (5), a first motor (6) is fixedly connected to the inner wall of the fourth hole, a guide plate (7) is fixedly connected to one end of an output shaft of the first motor (6), and the first motor (6) is electrically connected with the wireless communication device (19).

4. A novel water quality monitoring remote sensing instrument according to claim 3, characterized in that the top and bottom outer walls of the guide plate (7) are triangular.

5. The remote sensing instrument for monitoring water quality according to claim 1, wherein a limiting slide rod (8) is fixedly connected to the outer wall of the bottom of the housing (2), a limiting slide sleeve (9) is sleeved on the outer wall of the limiting slide rod (8), and the limiting slide sleeve (9) is fixedly connected with the outer wall of the telescopic water pipe (22).

6. The remote sensing instrument for monitoring water quality according to claim 1, wherein a filter plate (25) is fixedly connected to the inner wall of the telescopic water pipe (22).

7. The remote sensing instrument for monitoring water quality according to claim 1, wherein the outer wall of the bottom of the buoyancy plate (1) is fixedly connected with shunting knives (4), and the shunting knives (4) are symmetrically distributed.

8. The remote sensing instrument for monitoring water quality according to claim 1, wherein a liquid level meter (20) is arranged in the cavity, the liquid level meter (20) is fixedly connected with the mounting plate (17), and the liquid level meter (20) is electrically connected with the valve (24).

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