CN211426448U - Water source environment monitoring device based on big data - Google Patents

Abstract

The utility model discloses a water source environmental monitoring device based on big data, including kickboard and collecting tank, the battery is installed to one side at the inside top of kickboard, and the opposite side at the inside top of kickboard installs the air pump, the inside bottom of kickboard is close to one side of battery and installs the controller, and the intermediate position department of the inside bottom of kickboard installs step motor, the pivot is installed to step motor's output. The utility model discloses install and remove pipe, jet-propelled pipe, air guide hose and air pump, the gas of air pump suction is through jet-propelled pipe blowout, makes the device can remove in aqueous through the reaction force that jet-propelled production, is difficult for receiving the influence of aquatic debris, and the device installs step motor and pivot cooperation and uses, and step motor drives through the pivot and removes the pipe rotation, can adjust the jet-propelled direction of jet-propelled pipe to can adjust the moving direction of device, accommodation process is comparatively convenient.

Description

Water source environment monitoring device based on big data

Technical Field

The utility model relates to a water source monitoring facilities technical field specifically is a water source environmental monitoring device based on big data.

Background

The water source environment monitoring is the process of monitoring and measuring the types of pollutants in the water body, the concentration and the variation trend of various pollutants and evaluating the water quality condition. The monitoring range is very wide, including uncontaminated and contaminated natural water (rivers, lakes, seas and underground water) and various industrial drainage, so that the water quality condition can be mastered in real time, most of the existing water source environment monitoring devices based on big data collect water samples, and then the water quality detection results of detection personnel are compared with the big data, so that the water quality condition is judged, when the monitoring device is used, in order to collect the water samples at different positions, the paddle is often driven by a motor to rotate so that the device can move, the moving direction of the device is not convenient to adjust, the rotating process of the paddle is easy to be wound with impurities in water, so that the normal use of the device is influenced, meanwhile, when the existing water source environment monitoring devices based on big data are used, only one group of samples can be adopted, and a plurality of groups of samples cannot be adopted for comparison, the accuracy of the detection result is not favorably improved, the monitoring device cannot sample and detect water bodies at different depths at the same position, and the using effect of the device is poor.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a water source environmental monitoring device based on big data to solve the problem of proposing among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: a water source environment monitoring device based on big data comprises a floating plate and a liquid collecting tank, wherein a storage battery is installed on one side of the inner top of the floating plate, an air pump is installed on the other side of the inner top of the floating plate, a controller is installed on one side, close to the storage battery, of the inner bottom of the floating plate, a stepping motor is installed at the middle position of the inner bottom of the floating plate, a rotating shaft is installed at the output end of the stepping motor, the rotating shaft penetrates through the floating plate and extends to the outer portion of the floating plate, a moving pipe is installed at the bottom of the rotating shaft, an air injection pipe is installed on one side, close to the floating plate, of the inner portion of the moving pipe, a charging port is formed in the top of the floating plate, a mounting frame is installed at the top of the mounting frame, a signal receiver is installed at the middle, and electric telescopic handle's output all installs the fluid collection tank, the solenoid valve is all installed at the top that the kickboard one side was kept away from to the fluid collection tank, the intake pipe is installed to the input of air pump, and the output of air pump installs the air guide hose, the one end and the jet-propelled pipe intercommunication of air pump are kept away from to the air guide hose, signal receiver's output passes through the input electric connection of wire and controller, the output of controller passes through the wire respectively with the input electric connection of electric telescopic handle, step motor, solenoid valve and air pump, the output of the mouth that charges is connected with the input electricity of battery, the output of battery passes through the wire and is connected with the input electricity of electric telescopic handle, controller, step motor, signal receiver, solenoid valve and.

Preferably, the outside cover of kickboard is equipped with the gasbag, and the bottom of gasbag installs communicating pipe, the lid is installed to the one end that the gasbag was kept away from to communicating pipe.

Preferably, the middle position department of collection liquid tank bottom all installs the drain pipe, and the drain pipe is kept away from the one end of collection fluid tank and all installs sealed lid.

Preferably, the electric telescopic rods are provided with four groups, and the included angle between every two adjacent electric telescopic rods is ninety degrees.

Preferably, the outer sides of the liquid collecting tanks are provided with liquid level observation windows, and the outer sides of the liquid level observation windows are provided with scale marks.

Preferably, the air inlet pipe penetrates through the floating plate and extends to the outside of the floating plate, and a dustproof cloth bag is installed at one end, far away from the air pump, of the air inlet pipe.

Compared with the prior art, the beneficial effects of the utility model are that: the water source environment monitoring device based on big data is provided with the moving pipe, the air injection pipe, the air guide hose and the air pump, air pumped by the air pump is sprayed out through the air injection pipe, the device can move in water through reaction force generated by air injection and is not easily influenced by sundries in water, the device is provided with the stepping motor and the rotating shaft which are matched for use, the stepping motor drives the moving pipe to rotate through the rotating shaft, the air injection direction of the air injection pipe can be adjusted, so that the moving direction of the device can be adjusted, the adjusting process is convenient, meanwhile, the device is provided with a plurality of groups of liquid collecting tanks, a plurality of groups of water bodies can be sampled simultaneously, the device can be used for setting a comparison group, the accuracy of monitoring results can be improved, the device is provided with the electric telescopic rod and the electromagnetic valve, the liquid collecting tanks can be stretched into different positions in the, the water bodies with different depths can be sampled, so that the water quality conditions of the water bodies with different depths can be monitored.

Drawings

Fig. 1 is a schematic front sectional view of the present invention;

fig. 2 is a schematic front view of the present invention;

fig. 3 is a schematic top view of the mounting plate of the present invention;

fig. 4 is a schematic diagram of the circuit control of the present invention.

In the figure: 1. a floating plate; 2. an air bag; 3. a liquid collecting tank; 4. a charging port; 5. a mounting frame; 6. an electric telescopic rod; 7. a controller; 8. a storage battery; 9. a stepping motor; 10. a rotating shaft; 11. moving the tube; 12. a gas ejector tube; 13. an air guide hose; 14. a signal receiver; 15. mounting a plate; 16. an electromagnetic valve; 17. an air inlet pipe; 18. an air pump; 19. a drain pipe; 20. a communication pipe is provided.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides an embodiment: a water source environment monitoring device based on big data comprises a floating plate 1 and a liquid collecting tank 3, wherein a storage battery 8 is installed on one side of the inner top of the floating plate 1, an air pump 18 is installed on the other side of the inner top of the floating plate 1, the type of the air pump 18 can be VCH1028, a controller 7 is installed on one side, close to the storage battery 8, of the inner bottom of the floating plate 1, the type of the controller 7 can be MAM-100, a stepping motor 9 is installed at the middle position of the inner bottom of the floating plate 1, the type of the stepping motor 9 can be BYG43, a rotating shaft 10 is installed at the output end of the stepping motor 9, the rotating shaft 10 penetrates through the floating plate 1 and extends to the outer portion of the floating plate 1, a moving pipe 11 is installed at the bottom of the rotating shaft 10, an air injection pipe 12 is installed on one side, close to the floating plate 1, of the inner portion of the moving pipe 11, a charging port, a signal receiver 14 is arranged in the middle of the top of the mounting plate 15, the type of the signal receiver 14 can be TDX-28, electric telescopic rods 6 are uniformly arranged at the edge of the mounting plate 15, the type of the electric telescopic rods 6 can be EC-30, liquid collecting tanks 3 are arranged at the output ends of the electric telescopic rods 6, electromagnetic valves 16 are arranged at the tops of the sides, away from the floating plate 1, of the liquid collecting tanks 3, the type of the electromagnetic valves 16 can be BYM-L20H, an air inlet pipe 17 is arranged at the input end of an air pump 18, an air guide hose 13 is arranged at the output end of the air pump 18, one ends, away from the air pump 18, of the air guide hose 13 are communicated with an air injection pipe 12, the output end of the signal receiver 14 is electrically connected with the input end of a controller 7 through a lead, and the output end of the controller 7 is electrically connected with, the output end of the charging port 4 is electrically connected with the input end of the storage battery 8, and the output end of the storage battery 8 is electrically connected with the input ends of the electric telescopic rod 6, the controller 7, the stepping motor 9, the signal receiver 14, the electromagnetic valve 16 and the air pump 18 through conducting wires respectively.

In this implementation:

further, the outer side of the floating plate 1 is sleeved with the air bag 2, the bottom of the air bag 2 is provided with the communicating pipe 20, one end, far away from the air bag 2, of the communicating pipe 20 is provided with the cover body, the air bag 2 can be inflated through the communicating pipe 20, and buoyancy of the device is improved.

Further, the drain pipe 19 is installed at the middle position of the bottom of the liquid collecting tank 3, and the sealing cover is installed at the end, far away from the liquid collecting tank 3, of the drain pipe 19, so that a water sample inside the liquid collecting tank 3 can be taken out conveniently.

Further, electric telescopic handle 6 is provided with four groups, and the contained angle between the adjacent electric telescopic handle 6 is ninety degrees, can take a sample to the water all around of device simultaneously.

Further, the outside of collecting tank 3 all is provided with the liquid level observation window, and the outside of liquid level observation window all is provided with the scale mark, has been convenient for separate the inside liquid level of collecting tank 3.

Further, the air inlet pipe 17 penetrates through the floating plate 1 and extends to the outside of the floating plate 1, and a dustproof cloth bag is installed at one end, far away from the air pump 18, of the air inlet pipe 17, so that dust can be prevented from being sucked in.

The working principle is as follows: before use, the storage battery 8 is charged through the charging port 4, the storage battery 8 directly supplies power to the device during use, a user can send a signal instruction to the signal receiver 14 through external equipment, the signal receiver 14 transmits the received signal to the controller 7, the device is controlled through the controller 7 and is placed in water, the air pump 18 is controlled to be started, air pumped in by the air pump 18 is guided into the air ejector pipe 12 through the air guide hose 13 and is ejected out through the air ejector pipe 12, the device moves in the water through the counterforce generated by the air ejection, when the moving direction needs to be adjusted, the stepping motor 9 is controlled to be started, the stepping motor 9 drives the moving pipe 11 to rotate clockwise or anticlockwise for a fixed angle through the rotating shaft 10, the air ejecting direction of the air ejector pipe 12 is changed, the moving direction of the device is changed, when the device stops moving, the air pump 18 is controlled to be closed, monitoring personnel can move to different positions through the control device so, during the sampling, the output of the steerable electric telescopic handle of user 6 stretches out, 6 outputs of electric telescopic handle stretch out and push away into the aquatic with album fluid reservoir 3, the extension length of 6 outputs of detection personnel accessible control electric telescopic handle, thereby sample the water of the different degree of depth, treat that album fluid reservoir 3 stretches into when needing the degree of depth, solenoid valve 16 on the detection personnel control collection fluid reservoir 3 is opened, make the water source pass through solenoid valve 16 and get into collection fluid reservoir 3 and collect, detection personnel can sample through multiunit collection fluid reservoir 3 simultaneously, be convenient for set up the contrast group, improve monitoring result's accuracy and decide, when taking out the water sample, open the sealed lid of drain pipe 19 below, alright take out the water sample of storing in album fluid reservoir 3 and detect.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (6)

1. The utility model provides a water source environmental monitoring device based on big data, includes kickboard (1) and collection liquid jar (3), its characterized in that: the air pump type floating plate is characterized in that a storage battery (8) is installed on one side of the inner top of the floating plate (1), an air pump (18) is installed on the other side of the inner top of the floating plate (1), a controller (7) is installed on one side, close to the storage battery (8), of the inner bottom of the floating plate (1), a stepping motor (9) is installed at the middle position of the inner bottom of the floating plate (1), a rotating shaft (10) is installed at the output end of the stepping motor (9), the rotating shaft (10) penetrates through the floating plate (1) and extends to the outer portion of the floating plate (1), a moving pipe (11) is installed at the bottom of the rotating shaft (10), an air injection pipe (12) is installed on one side, close to the floating plate (1), of the inner portion of the moving pipe (11), a charging port (4) is arranged at the top of the floating plate (1), a mounting frame (5), and the intermediate position department at mounting panel (15) top installs signal receiver (14), the border position department of mounting panel (15) evenly installs electric telescopic handle (6), and electric telescopic handle's (6) output all installs liquid collection tank (3), the top of floating plate (1) one side is kept away from in liquid collection tank (3) all installs solenoid valve (16), intake pipe (17) are installed to the input of air pump (18), and air guide hose (13) are installed to the output of air pump (18), air guide hose (13) keep away from the one end of air pump (18) and jet-propelled pipe (12) intercommunication, the output of signal receiver (14) passes through the wire and the input electric connection of controller (7), the output of controller (7) pass through the wire respectively with electric telescopic handle (6), step motor (9), solenoid valve (16) and the input electric connection of air pump (18), the output end of the charging port (4) is electrically connected with the input end of a storage battery (8), and the output end of the storage battery (8) is electrically connected with the input ends of an electric telescopic rod (6), a controller (7), a stepping motor (9), a signal receiver (14), an electromagnetic valve (16) and an air pump (18) through wires respectively.

2. The big data based water source environment monitoring device as claimed in claim 1, wherein: the outside cover of kickboard (1) is equipped with gasbag (2), and communicating pipe (20) are installed to the bottom of gasbag (2), the lid is installed to the one end of gasbag (2) is kept away from in communicating pipe (20).

3. The big data based water source environment monitoring device as claimed in claim 2, wherein: the middle position department of collection fluid reservoir (3) bottom all installs drain pipe (19), and the sealed lid is all installed to the one end that collection fluid reservoir (3) was kept away from in drain pipe (19).

4. The big data based water source environment monitoring device as claimed in claim 1, wherein: the electric telescopic rods (6) are provided with four groups, and the included angle between every two adjacent electric telescopic rods (6) is ninety degrees.

5. The big data based water source environment monitoring device as claimed in claim 1, wherein: the outside of collection liquid jar (3) all is provided with the liquid level observation window, and the outside of liquid level observation window all is provided with the scale mark.

6. The big data based water source environment monitoring device as claimed in claim 1, wherein: the air inlet pipe (17) penetrates through the floating plate (1) and extends to the outside of the floating plate (1), and a dustproof cloth bag is installed at one end, far away from the air pump (18), of the air inlet pipe (17).

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