CN116183856B

CN116183856B - River water quality monitoring device

Info

Publication number: CN116183856B
Application number: CN202310237566.5A
Authority: CN
Inventors: 郭泽民; 段俊钊; 许桂平; 高云龙; 初艳华; 甄祥奎; 于江波
Original assignee: Shandong Suizhen Information Technology Co ltd
Current assignee: Shandong Suizhen Information Technology Co ltd
Priority date: 2023-03-14
Filing date: 2023-03-14
Publication date: 2024-02-09
Anticipated expiration: 2043-03-14
Also published as: CN116183856A

Abstract

The invention discloses a river water quality monitoring device which comprises a floating plate, wherein a support column is arranged at the center of the top of the floating plate, a solar mounting plate is arranged at the top of the support column, a solar photovoltaic plate is mounted on the solar mounting plate, a monitoring data display screen is arranged on the support column, a storage battery is arranged at the top of the floating plate and close to one end of the support column, a backflow channel is arranged at the bottom of the floating plate, a side plate is arranged at the bottom of the backflow channel, a gas storage cavity communicated with the bottom of the backflow channel is arranged at the center of the top of the side edge of the side plate, a monitoring mechanism is arranged in the gas storage cavity, an aerodynamic device is arranged on the monitoring mechanism, and the aerodynamic device is fixed at the position, close to the two ends of the bottom of the backflow channel, of the side edge of the side plate. The beneficial effects are that: different water depths are monitored differently, so that water quality and pollution conditions in different water depths can be found in time.

Description

River water quality monitoring device

Technical Field

The invention relates to the technical field of monitoring devices, in particular to a river water quality monitoring device.

Background

In the river water quality monitoring process, the traditional monitor directly inserts the fixed monitoring head into water, then manually inserts the fixed monitoring head into water, and adjusts the water depth condition to be monitored through the manual insertion depth.

Disclosure of Invention

The technical task of the invention is to provide a river water quality monitoring device for solving the problems.

The technical scheme of the invention is realized as follows:

the utility model provides a river water quality monitoring device, includes the kickboard, the top center department of kickboard is equipped with the support column, the top of support column is equipped with solar mounting panel, install solar photovoltaic board on the solar mounting panel, be equipped with monitoring data display screen on the support column, the kickboard top is close to support column one end is equipped with the battery, the bottom of kickboard is equipped with the backward flow passageway, the backward flow passageway bottom is equipped with the curb plate, the side top center department of curb plate be equipped with the gas storage cavity that the backward flow passageway bottom link up mutually, be equipped with monitoring mechanism in the gas storage cavity, be equipped with aerodynamic device on the monitoring mechanism, aerodynamic device fixes the curb plate side is close to backward flow passageway bottom both ends position department.

Preferably, a waterproof electric box is arranged outside the storage battery, and the electric box is fixed on one end, close to the supporting column, of the top of the floating plate.

Preferably, the aerodynamic device comprises a cylinder body arranged at two ends of the bottom of the backflow channel, piston plates II are arranged in the cylinder body, piston push rods II are arranged at the centers of the bottoms of the piston plates II, the piston push rods II penetrate through the cylinder body and extend to the lower portion of the side plate, belt pulleys III are arranged at the bottoms of the piston push rods II, belt shafts I are arranged in the middle of the belt pulleys in an penetrating mode, and punching plates are arranged at two ends of the belt shafts I.

Preferably, triangular brackets are arranged at two ends of the top of the cylinder body, a group of first belt pulleys are respectively arranged at two ends between corresponding sides of the triangular brackets, second belt pulleys are respectively arranged at one side below the first belt pulleys and at two sides of the cylinder body, and the first belt pulleys and the third belt pulleys are connected through first belt pulleys.

Preferably, two ends of the center position of the side edge of the side plate are respectively provided with a belt pulley IV, a belt II is arranged between the belt pulleys IV, and the two end parts of the belt are wound around the side edges of the belt pulley II, the belt pulley III and the belt pulley II and are fixedly connected with the two ends of the side edge of the side plate through fasteners.

Preferably, the monitoring mechanism comprises a first piston plate, the first piston plate is located in the gas storage cavity, a first piston push rod is arranged at the center of the bottom of the first piston plate, the first piston push rod penetrates through the bottom of the gas storage cavity and extends to the lower portion of the gas storage cavity, and the bottom of the first piston push rod extends to the top surface of the second belt.

Preferably, a cavity column is arranged below the middle of the second belt, the cavity column is fixed at the lower position of the side edge center of the side plate, an inner fixing block is arranged at the inner center of the cavity column, a channel is arranged in the middle of the inner fixing block, a vertical rod is longitudinally arranged in the channel, a fixing plate is arranged at the top of the vertical rod, the top of the fixing plate is fixed at the bottom center of the second belt, and a buffer spring is sleeved between the inner fixing block and the fixing plate on the upper portion of the vertical rod.

Preferably, the bottom of montant is equipped with the monitoring probe, monitoring probe side is equipped with the metal detection piece, montant one side is equipped with the side gear, the passageway is close to side gear one end is equipped with the gear mounting groove that link up, be equipped with in the gear mounting groove with side gear engaged with full gear.

Preferably, the cavity column is of a box structure with hollowed-out top and bottom, and the top surface of the cavity column is a smooth arc surface.

Compared with the prior art, the invention has the advantages and positive effects that:

1. this monitoring devices is provided with monitoring facilities and aerodynamic device through the below at the kickboard, wherein, be the linkage setting between aerodynamic device and the monitoring facilities, when the rivers below are relatively urgent or with the device down put in the time under the impulsive force effect of inside water, will impel the aerodynamic source that aerodynamic device produced to dash into the backward flow passageway, then enter into the gas storage cavity under the striking at both ends, impel the monitoring facilities of inside linkage to impress the submarine, carry out different monitoring to different water depths department, thereby can in time discover quality of water and pollution condition in the different water depths.

2. The driving of the aerodynamic device is realized not only through the pressure of the inside of the water flow emergency, but also by directly connecting a driver on the all-gear, the driver drives the all-gear to rotate, the monitoring mechanism is driven to lift, the aerodynamic device is pulled to operate, the aerodynamic source generated after the aerodynamic device operates can be stored, the follow-up energy source can be conveniently used, and the energy-saving and environment-friendly performance is realized.

3. Install the metal detection piece on the monitoring probe, can improve the accuracy of monitoring.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a general structural schematic diagram according to an embodiment of the present invention;

FIG. 2 is a schematic end view of an aerodynamic device according to an embodiment of the invention;

fig. 3 is a schematic diagram of a monitoring mechanism end structure according to an embodiment of the present invention.

In the figure:

1. a floating plate; 2. a support column; 3. a solar mounting plate; 4. a solar photovoltaic panel; 5. monitoring a data display screen; 6. a storage battery; 7. a return passage; 8. a side plate; 9. a gas storage cavity; 10. a monitoring mechanism; 11. an aerodynamic device; 12. a cylinder; 13. a second piston plate; 14. a piston push rod II; 15. a belt pulley III; 16. punching; 17. a tripod; 18. a first belt pulley; 19. a belt pulley II; 20. a first belt; 21. a belt pulley IV; 22. a second belt; 23. a first piston plate; 24. a first piston push rod; 25. a cavity column; 26. an inner fixing block; 27. a channel; 28. a vertical rod; 29. a fixing plate; 30. a buffer spring; 31. monitoring a probe; 32. a metal detecting sheet; 33. a side gear; 34. all gear.

Detailed Description

In order that the above objects, features and advantages of the invention will be more clearly understood, a further description of the invention will be rendered by reference to the appended drawings and examples. It should be noted that, in the case of no conflict, the embodiments of the present application and the features in the embodiments may be combined with each other.

The invention will be further described with reference to the drawings and the specific examples.

According to an embodiment of the invention, as shown in fig. 1-3:

the invention provides a river water quality monitoring device, which comprises a floating plate 1, wherein a support column 2 is arranged at the center of the top of the floating plate 1, a solar mounting plate 3 is arranged at the top of the support column 2, a solar photovoltaic panel 4 is arranged on the solar mounting plate 3, a monitoring data display screen 5 is arranged on the support column 2, a storage battery 6 is arranged at one end, close to the support column 2, of the top of the floating plate 1, a backflow channel 7 is arranged at the bottom of the backflow channel 7, a side plate 8 is arranged at the center of the top of the side edge of the side plate 8, a gas storage cavity 9 communicated with the bottom of the backflow channel 7 is arranged at the center of the top of the side edge of the side plate 8, a monitoring mechanism 10 is arranged in the gas storage cavity 9, an aerodynamic device 11 is arranged on the monitoring mechanism 10, and the aerodynamic device 11 is fixed at the position, close to the two ends of the bottom of the backflow channel 7, of the side edge of the side plate 8.

According to the illustration in fig. 1-2, the externally mounted waterproof electric box of the storage battery 6 is fixed on one end of the floating plate 1, which is close to the supporting column 2, the aerodynamic device 11 comprises a cylinder body 12 arranged on two ends of the bottom of the backflow channel 7, piston plates 13 are arranged in the cylinder body 12, piston push rods 14 are arranged at the center of the bottom of the piston plates 13, the piston push rods 14 penetrate through the cylinder body 12 and extend to the lower side of the side plate 8, belt pulleys 15 are arranged at the bottom of the piston push rods 14, belt shafts I are inserted in the middle of the belt pulleys 15, flushing plates 16 are arranged at two ends of the belt shafts I, triangular frames 17 are arranged at two ends of the top of the cylinder body 12, a group of belt pulleys 18 are arranged at two ends of the triangular frames 17, two sides of the belt pulleys 18 are arranged at two sides of the cylinder body 12, two belt pulleys 19 are arranged at two sides of the lower side of the belt pulley I18, the belt pulleys 18 and the belt pulleys 15 extend to the lower side of the side plate 8, belt pulleys 15 are respectively provided with belt pulleys 15, belt pulleys 15 are respectively connected with belt pulleys 21, and the end parts 21 are respectively arranged at the two sides of the belt pulleys 8, and the two sides of the belt pulleys are respectively connected with the two side plates 19, and the two sides of the belt pulleys are respectively connected with the two side plates 8 through the belt pulleys 19, and the two sides of the two side plates are respectively, and the two side plates are respectively connected with the two side plates 21, and the two side plates are respectively, and the two side plate sides are respectively connected with the two side plate fastener pieces and the two fastener pieces are respectively and the fastener piece, and the fastener is respectively.

In addition, according to the illustration in fig. 3, the monitoring mechanism 10 comprises a first piston plate 23, the first piston plate 23 is positioned in the air storage cavity 9, a first piston push rod 24 is arranged at the center of the bottom of the first piston plate 23, the first piston push rod 24 penetrates through the bottom of the air storage cavity 9 and extends below the air storage cavity 9, the bottom of the first piston push rod 24 extends to the top surface of the second belt 22, a cavity column 25 is arranged below the middle of the second belt 22, the cavity column 25 is fixed at the lower position of the side edge center of the side plate 8, an inner fixing block 26 is arranged at the inner center of the cavity column 25, a channel 27 is arranged at the middle of the inner fixing block 26, a vertical rod 28 is longitudinally arranged in the channel 27, the utility model discloses a portable electronic device, including belt two 22, montant 28, cavity post 25, including the montant 28, the top is equipped with fixed plate 29, the top of fixed plate 29 is fixed the bottom center department of belt two 22, the upper portion of montant 28 is located the interior fixed block 26 with the cover is equipped with buffer spring 30 between the fixed plate 29, the bottom of montant 28 is equipped with monitoring probe 31, monitoring probe 31 side is equipped with metal detection piece 32, montant 28 one side is equipped with side gear 33, passageway 27 is close to side gear 33 one end is equipped with the gear mounting groove that link up, be equipped with in the gear mounting groove with side gear 33 engaged with full gear 34, cavity post 25 sets up to top and bottom and is hollow-out box formula structure, wherein, the top face of cavity post 25 is smooth arcwall face.

Detailed methods and functions of the present embodiment:

when the device is put into water to be monitored, the bottom flushing plate 16 is pressed by internal water pressure in the sinking process of the device, the flushing plate 16 is upwards to drive the piston push rod II 14 to push into the cylinder body 12, air pressure is generated in the cylinder body 12, the air pressure flows into the backflow channel 7 at the same time, finally air flows at two ends impact the piston plate I23 in the air storage cavity 9 after the middle junction of the backflow channel 7 is impacted, the piston plate I23 is pressed by the bottom piston push rod I24 downwards after being pressed by the piston plate I23, at the moment, the piston push rod I24 is pressed by the middle part of the bottom belt II 22 downwards, and the middle part of the belt II 22 is kept in a tight state with the belt pulley moderately, when the middle part of the belt II 22 is pressed downwards, the piston push rod II 14 is pushed into the cylinder body, the vertical rod 28 extends out of the bottom of the cavity column 25, and the bottom monitoring probe 31 is enabled to monitor water quality in the water bottom, and data obtained through monitoring are transmitted to the upper monitoring data display screen 5, and data information is stored.

When the device is completely put into the water, the floating plate 1 floats on the water surface, and the water bottom is in a static state, that is, no water flow is generated, at this time, the full gear 34 can be directly driven to rotate by driving the driver connected with the full gear 34, and then the monitoring depth of the monitoring probe 31 is adjusted.

The present invention can be easily implemented by those skilled in the art through the above specific embodiments. It should be understood that the invention is not limited to the particular embodiments described above. Based on the disclosed embodiments, a person skilled in the art may combine different technical features at will, so as to implement different technical solutions.

Claims

1. The river water quality monitoring device is characterized by comprising a floating plate (1), wherein a support column (2) is arranged at the center of the top of the floating plate (1), a solar mounting plate (3) is arranged at the top of the support column (2), a solar photovoltaic plate (4) is arranged on the solar mounting plate (3), a monitoring data display screen (5) is arranged on the support column (2), a storage battery (6) is arranged at the top of the floating plate (1) and is close to one end of the support column (2), a backflow channel (7) is arranged at the bottom of the floating plate (1), a side plate (8) is arranged at the bottom of the backflow channel (7), a gas storage cavity (9) communicated with the bottom of the backflow channel (7) is arranged at the center of the top of the side edge of the side plate (8), a monitoring mechanism (10) is arranged in the gas storage cavity (9), and an aerodynamic device (11) is arranged on the monitoring mechanism (10) and is fixed at the position of the side edge of the side plate (8) and is close to two ends of the bottom of the backflow channel (7);

the aerodynamic device (11) is including setting up cylinder body (12) on backflow channel (7) bottom both ends, all be equipped with piston board two (13) in cylinder body (12), piston board two (13)'s bottom center department all is equipped with piston push rod two (14), piston push rod two (14) all run through in cylinder body (12) extend to the below of curb plate (8), piston push rod two (14)'s bottom all is equipped with belt pulley three (15), the middle part of belt pulley three (15) all alternates and is equipped with belt axle one, belt axle one's both ends all are equipped with punch plate (16), cylinder body (12)'s top both ends all are equipped with tripod (17), tripod (17) correspond both ends between the side and are equipped with a set of belt pulley one (18), one side of below of belt pulley one (18) just is located cylinder body (12) both sides department all is equipped with belt pulley two (19), belt pulley one (18) with between belt pulley three (15) all be equipped with belt pulley three (20), belt pulley two (21) are equipped with belt pulley two (21), belt pulley two (21) are equipped with from four sides (21), belt pulley two ends (21) are equipped with, belt end (21) are equipped with, four belt ends are equipped with each other, and are equipped with one belt pulley (19 The side edge of the second belt pulley (19) winds around and the end part is fixedly connected with the two ends of the side edge of the side plate (8) through a fastener.

2. A river water quality monitoring device according to claim 1, characterized in that the outside of the accumulator (6) is provided with a waterproof electric box which is fixed on one end of the top of the floating plate (1) close to the support column (2).

3. The river water quality monitoring device according to claim 1, wherein the monitoring mechanism (10) comprises a first piston plate (23), the first piston plate (23) is located in the air storage cavity (9), a first piston push rod (24) is arranged at the center of the bottom of the first piston plate (23), the first piston push rod (24) penetrates through the bottom of the air storage cavity (9) and extends to the lower side of the air storage cavity (9), and the bottom of the first piston push rod (24) extends to the top surface of the second belt (22).

4. A river water quality monitoring device according to claim 3, characterized in that a cavity column (25) is arranged below the middle part of the second belt (22), the cavity column (25) is fixed at the lower position of the side edge center of the side plate (8), an inner fixing block (26) is arranged at the inner center of the cavity column (25), a channel (27) is arranged in the middle part of the inner fixing block (26), a vertical rod (28) is longitudinally arranged in the channel (27), a fixing plate (29) is arranged at the top of the vertical rod (28), the top of the fixing plate (29) is fixed at the bottom center of the second belt (22), and a buffer spring (30) is sleeved between the inner fixing block (26) and the fixing plate (29) at the upper part of the vertical rod (28).

5. The river water quality monitoring device according to claim 4, wherein a monitoring probe (31) is arranged at the bottom of the vertical rod (28), a metal detection sheet (32) is arranged on the side of the monitoring probe (31), a side gear (33) is arranged on one side of the vertical rod (28), a through gear mounting groove is formed in one end, close to the side gear (33), of the channel (27), and a full gear (34) meshed with the side gear (33) is arranged in the gear mounting groove.

6. The river water quality monitoring device according to claim 5, wherein the cavity column (25) is of a box structure with hollowed top and bottom, and the top surfaces of the cavity column (25) are smooth arc surfaces.