CN215415384U - Remote hydrographic water environment automatic monitoring system platform - Google Patents

Abstract

The utility model belongs to the technical field of monitoring equipment, in particular to a remote automatic monitoring system platform for a hydrological water environment, which aims at solving the problems that the existing monitoring system platform is inconvenient to use, cannot well ventilate and radiate a device, is easy to damage the device due to long-time load, causes certain loss and affects the accuracy of a monitoring result. The utility model is convenient to use, can well ventilate and radiate the device, ensures that equipment is not easy to damage, and improves the accuracy of a monitoring result.

Description

Remote hydrographic water environment automatic monitoring system platform

Technical Field

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

Background

A remote automatic monitoring system platform for hydrological water environment is a device special for monitoring water quality environment. The water environment refers to the environment of the space where water is formed, distributed and transformed in nature, and refers to the water body surrounding the crowd space and capable of directly or indirectly influencing the life and development of human beings. At the earth's surface, the water area accounts for about 71% of the earth's surface area. The water consists of two parts, namely ocean water and land water, which are 97.28 percent and 2.72 percent of the total water amount respectively. The latter accounts for a small proportion of the total amount and the environment of the space is very complex. Hydrology refers to various phenomena in nature such as water change and movement. The hydrological monitoring system is suitable for hydrological departments to carry out real-time monitoring on hydrological parameters such as rivers, lakes, reservoirs, channels, underground water and the like, and the monitoring content comprises the following steps: water level, flow rate, rainfall (snow), evaporation, silt, slush, soil moisture, water quality, and the like. Water is in a dynamic equilibrium state of continuous circulation on the earth. The basic chemical components and contents of natural water reflect the original physicochemical properties of the natural water in the circulation process of different natural environments, and are the basic basis for researching the existence, migration and conversion of elements in the water environment and evaluating the environmental quality (or pollution degree) and water quality. The water environment mainly comprises a surface water environment and a groundwater environment. Surface water environments include rivers, lakes, reservoirs, oceans, ponds, marshes, glaciers, and the like, and groundwater environments include spring water, shallow groundwater, deep groundwater, and the like. The water environment is one of the basic elements constituting the environment, is an important place for the survival and development of the human society and is also the field which is most seriously interfered and damaged by human beings. The pollution and destruction of the aqueous environment has become one of the major environmental problems in the world today. The water environment monitoring is a unified timing or random monitoring to the quality and quantity of water and various artificial and natural factors influencing the ecology and the environment quality in the water body according to the water circulation rule (precipitation, surface water and underground water).

However, the existing monitoring system platform is inconvenient to use, can not well ventilate and radiate the device, is easy to damage equipment due to long-time loading, causes certain loss, and affects the accuracy of a monitoring result.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the defects that the existing monitoring system platform is inconvenient to use, cannot well ventilate and radiate a device, is easy to damage equipment due to long-time loading, causes certain loss and influences the accuracy of a monitoring result, and provides the remote hydrographic water environment automatic monitoring system platform.

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

remote hydrology water environment automatic monitoring system platform, including the kickboard, the bottom symmetry fixed mounting of kickboard has two control valves, the top fixed mounting of kickboard has solar panel, the top fixed mounting of kickboard has the control box, one side slidable mounting of kickboard has monitoring devices, the top fixed mounting of kickboard has thrust unit, the top fixed mounting of kickboard has the installation cover, the symmetry has been seted up two ventilation holes on the installation cover, symmetrical fixed mounting has two safety covers on the installation cover, fixed mounting has electric putter on the top inner wall of installation cover, fixed mounting has the mounting panel on electric putter's the output shaft, fixed mounting has drive arrangement on the mounting panel, the bottom fixed mounting of mounting panel has bellows, the bottom fixed mounting of bellows has a plurality of shower nozzle, transmission is installed to the installation cover internal rotation, symmetrical slidable mounting has two baffles in the installation cover.

Preferably, monitoring devices includes slide bar and monitoring head, and slide bar slidable mounting is in one side of kickboard, and monitoring head fixed mounting is in the bottom of slide bar, and one side fixed mounting of kickboard has the survey board, and slide bar slidable mounting is on the curb plate.

Preferably, the pushing device comprises a hydraulic rod, the hydraulic rod is fixedly installed at the top of the floating plate, and an output shaft of the hydraulic rod is fixedly connected with the sliding rod.

Preferably, the driving device comprises two push plates which are symmetrically and fixedly arranged on the mounting plate.

Preferably, transmission includes two telescopic links, and two telescopic links symmetry rotate to be installed in the installation cover, and two telescopic links rotate with two baffles respectively and are connected, and symmetrical fixed mounting has two bull sticks in the installation cover, and two telescopic links rotate respectively and install on two bull sticks.

Preferably, two chutes are symmetrically formed in the mounting cover, limiting rods are fixedly mounted in the two chutes, supporting rods are slidably mounted on the two limiting rods, and the two baffles are fixedly mounted on the two supporting rods respectively.

Preferably, two equal fixed mounting has the pressure spring in the spout, two pressure springs respectively with two bracing pieces fixed connection.

Compared with the prior art, the utility model has the advantages that:

(1) the scheme is provided with the floating plate, the control valve, the solar panel, the control box, the sliding rod, the monitoring head and the hydraulic rod, so that the device can be controlled to move conveniently through the control valve, and the monitoring head is placed in the water at the position needing to be used, so that the device is more convenient to use;

(2) this scheme is keeping in charge of time measuring quality of water owing to set up installation cover, ventilation hole, safety cover, electric putter, mounting panel, bellows, shower nozzle, spout, gag lever post, bracing piece, baffle, pressure spring, telescopic link, push pedal, can dispel the heat and ventilate in the installation cover to the control box through bellows, has ensured the use of device, has avoided the damage of device, has improved the accuracy of monitoring result.

The utility model is convenient to use, can well ventilate and radiate the device, ensures that equipment is not easy to damage, and improves the accuracy of a monitoring result.

Drawings

Fig. 1 is a schematic structural diagram of a remote hydrographic water environment automatic monitoring system platform provided by the utility model;

FIG. 2 is a schematic view of a three-dimensional structure of a floating plate, an installation cover and a protection cover of the remote automatic monitoring system platform for the hydrological water environment provided by the utility model;

fig. 3 is a schematic structural diagram of part a of a remote hydrographic water environment automatic monitoring system platform fig. 1 according to the present invention;

fig. 4 is a schematic system structure diagram of a remote hydrographic water environment automatic monitoring system platform provided by the present invention.

In the figure: 1. a floating plate; 2. a control valve; 3. a solar panel; 4. a control box; 5. a slide bar; 6. a monitoring head; 7. a hydraulic lever; 8. mounting a cover; 9. a vent hole; 10. a protective cover; 11. an electric push rod; 12. mounting a plate; 13. an air box; 14. a spray head; 15. a chute; 16. a limiting rod; 17. a support bar; 18. a baffle plate; 19. a pressure spring; 20. a telescopic rod; 21. a push plate.

Detailed Description

The technical solutions in the embodiments will be described clearly and completely with reference to the drawings in the embodiments, and it is obvious that the described embodiments are only a part of the embodiments, but not all embodiments.

Example one

Referring to fig. 1-4, a remote hydrographic water environment automatic monitoring system platform comprises a floating plate 1, two control valves 2 are symmetrically and fixedly installed at the bottom of the floating plate 1, a solar panel 3 is fixedly installed at the top of the floating plate 1, a control box 4 is fixedly installed at the top of the floating plate 1, a monitoring device is slidably installed at one side of the floating plate 1, a pushing device is fixedly installed at the top of the floating plate 1, an installation cover 8 is fixedly installed at the top of the floating plate 1, two ventilation holes 9 are symmetrically formed in the installation cover 8, two protection covers 10 are symmetrically and fixedly installed on the installation cover 8, an electric push rod 11 is fixedly installed on the inner wall of the top of the installation cover 8, an installation plate 12 is fixedly installed on an output shaft of the electric push rod 11, a driving device is fixedly installed on the installation plate 12, an air box 13 is fixedly installed at the bottom of the installation plate 12, and a plurality of spray nozzles 14 are fixedly installed at the bottom of the air box 13, the mounting cover 8 is rotatably provided with a transmission device, and the mounting cover 8 is symmetrically and slidably provided with two baffles 18.

In this embodiment, monitoring devices includes slide bar 5 and monitoring head 6, and 5 slidable mounting of slide bar are in one side of kickboard 1, and 6 fixed mounting of monitoring head are in the bottom of slide bar 5, and one side fixed mounting of kickboard 1 has the survey board, and 5 slidable mounting of slide bar have ensured the stable slip of slide bar 5 on the curb plate.

In this embodiment, thrust unit includes hydraulic stem 7, and hydraulic stem 7 fixed mounting is at the top of kickboard 1, and the output shaft and the slide bar 5 fixed connection of hydraulic stem 7 can drive slide bar 5 through hydraulic stem 7 and remove.

In this embodiment, the driving device includes two pushing plates 21, and the two pushing plates 21 are symmetrically and fixedly mounted on the mounting plate 12, so that the mounting plate 12 can drive the two telescopic rods 20 to move when moving.

In this embodiment, transmission includes two telescopic links 20, and two telescopic links 20 symmetry rotate to be installed in installation cover 8, and two telescopic links 20 rotate with two baffles 18 respectively and are connected, and symmetrical fixed mounting has two bull sticks in the installation cover 8, and two telescopic links 20 rotate respectively and install on two bull sticks for can drive two baffles 18 and remove when two telescopic links 20 move.

In this embodiment, two chutes 15 have been seted up to the symmetry in the installation cover 8, equal fixed mounting has gag lever post 16 in two chutes 15, and equal slidable mounting has bracing piece 17 on two gag lever posts 16, and two baffles 18 are fixed mounting respectively on two bracing pieces 17, have ensured the steady removal of two baffles 18.

In this embodiment, the two sliding grooves 15 are internally and fixedly provided with the pressure springs 19, and the two pressure springs 19 are respectively and fixedly connected with the two supporting rods 17, so that the two baffle plates 18 can be reset when losing thrust.

The working principle is as follows: when using monitoring devices, can remove in aqueous through 2 controlling means of control valve, with hydraulic stem 7 access power when reacing the assigned position, start hydraulic stem 7, hydraulic stem 7 drives slide bar 5 and removes, slide bar 5 drives monitoring head 6 and removes, it carries out real-time supervision to remove monitoring head 6 to aquatic, insert the power with electric putter 11 simultaneously, start electric putter 11, electric putter 11 drives mounting panel 12 and removes, mounting panel 12 drives fan 13 and removes, make bellows 13 be close to control box 4, mounting panel 12 drives two push pedal 21 and removes, two push pedal 21 drive two telescopic links 20 and rotate, two telescopic links 20 drive two baffles 18 and remove, make two ventilation holes 9 opened, the ventilation and heat dissipation in the installation cover 8 has been ensured, the effectual monitoring effect that has improved.

Example two

Referring to fig. 1-4, a remote hydrographic water environment automatic monitoring system platform comprises a floating plate 1, two control valves 2 are symmetrically and fixedly installed at the bottom of the floating plate 1, a solar panel 3 is fixedly installed at the top of the floating plate 1, a control box 4 is fixedly installed at the top of the floating plate 1, a monitoring device is slidably installed at one side of the floating plate 1, a pushing device is fixedly installed at the top of the floating plate 1, an installation cover 8 is fixedly installed at the top of the floating plate 1, two ventilation holes 9 are symmetrically formed in the installation cover 8, two protection covers 10 are symmetrically and fixedly installed on the installation cover 8, an electric push rod 11 is fixedly installed on the inner wall of the top of the installation cover 8, an installation plate 12 is fixedly installed on an output shaft of the electric push rod 11, a driving device is fixedly installed on the installation plate 12, an air box 13 is fixedly installed at the bottom of the installation plate 12, and a plurality of spray nozzles 14 are fixedly installed at the bottom of the air box 13, the transmission is installed to 8 internal rotations of installation cover, and symmetrical slidable mounting has two baffles 18 in the installation cover 8, can install a camera additional on kickboard 1, and camera movable mounting can observe the condition in waters through the camera at the top of kickboard 1, avoids damaging the device such as striking.

In this embodiment, monitoring devices includes slide bar 5 and monitoring head 6, and 5 slidable mounting of slide bar are in one side of kickboard 1, and 6 fixed mounting of monitoring head are in the bottom of slide bar 5, and one side fixed mounting of kickboard 1 has the survey board, and 5 slidable mounting of slide bar have ensured the stable slip of slide bar 5 on the curb plate.

In this embodiment, thrust unit includes hydraulic stem 7, and hydraulic stem 7 fixed mounting is at the top of kickboard 1, and the output shaft and the slide bar 5 fixed connection of hydraulic stem 7 can drive slide bar 5 through hydraulic stem 7 and remove.

In this embodiment, the driving device includes two pushing plates 21, and the two pushing plates 21 are symmetrically and fixedly mounted on the mounting plate 12, so that the mounting plate 12 can drive the two telescopic rods 20 to move when moving.

In this embodiment, transmission includes two telescopic links 20, and two telescopic links 20 symmetry rotate to be installed in installation cover 8, and two telescopic links 20 rotate with two baffles 18 respectively and are connected, and symmetrical fixed mounting has two bull sticks in the installation cover 8, and two telescopic links 20 rotate respectively and install on two bull sticks for can drive two baffles 18 and remove when two telescopic links 20 move.

In this embodiment, two chutes 15 have been seted up to the symmetry in the installation cover 8, equal fixed mounting has gag lever post 16 in two chutes 15, and equal slidable mounting has bracing piece 17 on two gag lever posts 16, and two baffles 18 are fixed mounting respectively on two bracing pieces 17, have ensured the steady removal of two baffles 18.

In this embodiment, the two sliding grooves 15 are internally and fixedly provided with the pressure springs 19, and the two pressure springs 19 are respectively and fixedly connected with the two supporting rods 17, so that the two baffle plates 18 can be reset when losing thrust.

The difference between the second embodiment and the first embodiment is that: install a camera additional on kickboard 1, camera movable mounting is at the top of kickboard 1, can observe the condition in waters through the camera, avoids damaging the device such as striking.

The above descriptions are only preferred embodiments of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the scope of the present invention, and the technical solutions and the utility model concepts of the present invention are equivalent to, replaced or changed.

Claims (7)

1. The remote automatic monitoring system platform for the hydrological water environment comprises a floating plate (1) and is characterized in that two control valves (2) are symmetrically and fixedly installed at the bottom of the floating plate (1), a solar panel (3) is fixedly installed at the top of the floating plate (1), a control box (4) is fixedly installed at the top of the floating plate (1), a monitoring device is slidably installed on one side of the floating plate (1), a pushing device is fixedly installed at the top of the floating plate (1), an installation cover (8) is fixedly installed at the top of the floating plate (1), two ventilation holes (9) are symmetrically formed in the installation cover (8), and two protection covers (10) are symmetrically and fixedly installed on the installation cover (8);

the top inner wall of the mounting cover (8) is fixedly provided with an electric push rod (11), an output shaft of the electric push rod (11) is fixedly provided with a mounting plate (12), the mounting plate (12) is fixedly provided with a driving device, the bottom of the mounting plate (12) is fixedly provided with an air box (13), the bottom of the air box (13) is fixedly provided with a plurality of spray heads (14), the mounting cover (8) is rotatably provided with a transmission device, and the mounting cover (8) is internally provided with two baffles (18) in a symmetrical and sliding manner.

2. The remote automatic monitoring system platform for the hydrographic water environment according to claim 1, wherein the monitoring device comprises a sliding rod (5) and a monitoring head (6), the sliding rod (5) is slidably mounted on one side of the floating plate (1), and the monitoring head (6) is fixedly mounted at the bottom end of the sliding rod (5).

3. The remote hydrographic water environment automatic monitoring system platform of claim 1, characterized in that, thrust unit includes hydraulic stem (7), and hydraulic stem (7) fixed mounting is at the top of kickboard (1), and the output shaft and the slide bar (5) fixed connection of hydraulic stem (7).

4. The remote automatic monitoring system platform for the hydrographic water environment according to claim 1, characterized in that the driving device comprises two push plates (21), and the two push plates (21) are symmetrically and fixedly installed on the installation plate (12).

5. The remote hydrographic water environment automatic monitoring system platform of claim 1, characterized in that, transmission includes two telescopic links (20), two telescopic links (20) symmetry rotation is installed in installing cover (8), two telescopic links (20) respectively with two baffle (18) rotation connection.

6. The remote hydrographic water environment automatic monitoring system platform of claim 1, characterized in that, two chutes (15) have been seted up in the installation cover (8) symmetry, and gag lever post (16) have all been fixed mounting in two chutes (15), and the bracing piece (17) has all been installed on two gag lever posts (16) in a sliding manner, and two baffles (18) are fixed mounting respectively on two bracing pieces (17).

7. The remote hydrographic water environment automatic monitoring system platform of claim 6, characterized in that, pressure spring (19) is fixed to both of the chutes (15), and the two pressure springs (19) are respectively and fixedly connected with the two support rods (17).

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