CN216559106U - Ecological environment monitoring device - Google Patents

Abstract

The utility model discloses an ecological environment monitoring device, which relates to the technical field of ecological environment monitoring and comprises a base, wherein two electric telescopic rods are arranged at the top of the base, the ecological environment monitoring device is provided with a piston cylinder, a rotating rod and a second hose, the output end of a second servo motor drives the rotating rod to rotate, so that a cam rotates reversely, the circular end of the cam rotates towards a push plate, a return spring pushes the push plate to move towards the cam, water enters a fourth electromagnetic valve through a first hose and then enters the interior of the fourth electromagnetic valve through the fourth electromagnetic valve, the convex end of the cam rotates towards the push plate, so that the push plate pushes a piston rod to move in a return way, a piston block moves in a return way, the water in the piston cylinder enters a fixed pipe through the second electromagnetic valve and then enters the interior of the second hose through a rotary joint and then is discharged into a water body or a carried water tank through a water head, the weight of the base is reduced, and the device is convenient to move.

Description

Ecological environment monitoring device

Technical Field

The utility model relates to the technical field of ecological environment monitoring, in particular to an ecological environment monitoring device.

Background

In the lake-side range, wetland plants and habitat, waterfowl and other wetland animal monitoring is carried out, particularly, continuous dynamic monitoring of the waterfowl is carried out in a targeted manner during a ship noise simulation test, and an ecological environment monitoring device is required. However, the existing ecological environment monitoring device is heavy, and when the device is moved, the weight of the ecological environment monitoring device cannot be effectively reduced, so that the ecological environment monitoring device is inconvenient to move.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects of the prior art, the utility model provides an ecological environment monitoring device, which solves the problems in the background technology.

In order to achieve the purpose, the utility model is realized by the following technical scheme: an ecological environment monitoring device comprises a base, wherein two electric telescopic rods are arranged at the top of the base, the telescopic ends of the two electric telescopic rods are provided with a top plate, a storage box is fixedly arranged at the top of the top plate, a connecting groove is formed in the top plate, a rotating rod is rotatably connected to the bottom of an inner cavity of the connecting groove, a cam is sleeved on the outer side of the rotating rod, a piston cylinder is fixedly arranged in the connecting groove, a piston block is slidably connected in the piston cylinder, a piston rod is arranged at one end of the piston block, the other end of the piston rod extends to the outer side of the piston cylinder and is provided with a push plate, a reset spring is sleeved on the outer side of the piston rod, a second electromagnetic valve is arranged on one side of the piston cylinder, a first electromagnetic valve is arranged on one side of the piston cylinder and below the second electromagnetic valve, a three-way joint is arranged in the connecting groove, one end of the second electromagnetic valve is connected with one end of the three-way joint, one end of the first electromagnetic valve is connected with the other end of the three-way joint, a first hose is arranged inside the connecting groove, a third electromagnetic valve is arranged on one side of the piston cylinder and below the first electromagnetic valve, a fourth electromagnetic valve is arranged on one side of the piston cylinder and below the third electromagnetic valve, the third electromagnetic valve and the fourth electromagnetic valve are both connected with one end of the first hose, and the bottom end of the first hose extends into the base.

Preferably, the fixed slot has been seted up to inside one side that just is located the spread groove of roof, fixed slot inner chamber is provided with the connecting plate, the top of connecting plate is rotated and is connected with the pipe roller, the outside winding of pipe roller has the second hose, the inside connecting pipe that is provided with of pipe roller, the one end of second hose is connected with the one end of connecting pipe, the bottom of connecting plate is provided with rotary joint, rotary joint's top is connected with the one end of connecting pipe, rotary joint's bottom is provided with fixed pipe, the one end of fixed pipe extends to inside and the remaining one end with three way connection of spread groove and is connected.

Preferably, the top of roof is provided with first servo motor, first servo motor's output is connected with the top of pipe roller.

Preferably, the bottom of roof is provided with second servo motor, second servo motor's output is connected with the bottom of dwang.

Preferably, a storage cavity is formed in the storage box, two threaded rods are rotatably connected to the inner cavity of the storage cavity, moving blocks are connected to the outer sides of the threaded rods in a threaded mode, and a monitoring mechanism is arranged between the two moving blocks.

Preferably, the inside storage chamber of having seted up of storage box, the transmission groove has been seted up to the inside below that just is located the storage chamber of storage box, the top of dwang extends to the inside and cover of transmission groove and is equipped with second bevel gear, the top of transmission inslot chamber and the both sides that are located the dwang all are provided with the connecting block, one side of connecting block all rotates and is connected with the axis of rotation, the one end of axis of rotation all overlaps and is equipped with first bevel gear, first bevel gear all is connected with second bevel gear meshing, the other end of axis of rotation all extends to one side of connecting block and overlaps and is equipped with fourth bevel gear, the bottom of threaded rod all extends to the inside and cover of transmission groove and is equipped with third bevel gear, third bevel gear all is connected with fourth bevel gear meshing.

Preferably, a baffle is arranged at the top of the monitoring mechanism and above the storage box.

The utility model provides an ecological environment monitoring device, which has the following beneficial effects:

1. the ecological environment monitoring device is provided with a piston cylinder, a rotating rod and a second hose, a first electromagnetic valve and a third electromagnetic valve are closed, the second electromagnetic valve and a fourth electromagnetic valve are opened, then an output end of a second servo motor drives the rotating rod to rotate, so that a cam rotates reversely, a round end of the cam rotates towards a push plate, a reset spring pushes the push plate to move towards the cam, water enters the fourth electromagnetic valve through the first hose and then enters the piston cylinder through the fourth electromagnetic valve, a convex end of the cam rotates towards the push plate, so that the push plate pushes a piston rod to reset and move, a piston block resets and moves, water in the piston cylinder enters the fixed pipe through the second electromagnetic valve and enters the second hose through a rotary joint, and then is discharged into a water body or a carried water tank through a water head, the weight of the base is reduced, and the device is convenient to move.

2. This ecological environment monitoring devices, through being provided with second bevel gear, axis of rotation and threaded rod, the dwang rotates and drives second bevel gear antiport, make first bevel gear antiport, make axis of rotation antiport, fourth bevel gear beats third bevel gear antiport this moment, make threaded rod antiport, make the movable block drive monitoring mechanism move down, make monitoring mechanism move to the inside of storage chamber, when the bottom of baffle and the top contact of storage box, the inside water of base discharges, then take out the water tank that the flood peak was perhaps carried in near water follow, make monitoring mechanism can move to the storage intracavity portion, prevent at the removal in-process, cause the collision to monitoring mechanism, make monitoring mechanism receive the condition emergence of damage.

Drawings

FIG. 1 is a schematic view of the internal structure of the present invention;

FIG. 2 is an enlarged view taken at A of FIG. 1 in accordance with the present invention;

FIG. 3 is an enlarged view of FIG. 1 at B according to the present invention;

FIG. 4 is an enlarged view of FIG. 1 at C according to the present invention;

fig. 5 is an enlarged view of fig. 1 at D according to the present invention.

In the figure: 1. a base; 2. an electric telescopic rod; 3. a top plate; 4. a storage box; 5. a storage chamber; 6. connecting grooves; 7. rotating the rod; 8. a cam; 9. a piston cylinder; 10. a piston rod; 11. pushing the plate; 12. a return spring; 13. a piston block; 14. a three-way joint; 15. a first solenoid valve; 16. a second solenoid valve; 17. fixing grooves; 18. a first servo motor; 19. a tube roll; 20. a connecting pipe; 21. a rotary joint; 22. a fixed tube; 23. a first hose; 24. a third electromagnetic valve; 25. a fourth solenoid valve; 26. a second hose; 27. a rotating shaft; 28. a first bevel gear; 29. a second bevel gear; 30. a transmission groove; 31. a third bevel gear; 32. a fourth bevel gear; 33. a threaded rod; 34. a moving block; 35. a monitoring mechanism; 36. a baffle plate; 37. a second servo motor; 38. a connecting plate; 39. and (4) connecting the blocks.

Detailed Description

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

Referring to fig. 1 to 5, the present invention provides a technical solution: an ecological environment monitoring device comprises a base 1, wherein two electric telescopic rods 2 are arranged at the top of the base 1, top plates 3 are arranged at the telescopic ends of the two electric telescopic rods 2, a storage box 4 is fixedly arranged at the top of each top plate 3, a connecting groove 6 is formed in the top plate 3, a rotating rod 7 is rotatably connected to the bottom of an inner cavity of the connecting groove 6, a cam 8 is sleeved on the outer side of the rotating rod 7, a piston cylinder 9 is fixedly arranged in the connecting groove 6, a piston block 13 is slidably connected to the inner part of the piston cylinder 9, a piston rod 10 is arranged at one end of the piston block 13, the other end of the piston rod 10 extends to the outer side of the piston cylinder 9 and is provided with a push plate 11, a return spring 12 is sleeved on the outer side of the piston rod 10, a second electromagnetic valve 16 is arranged at one side of the piston cylinder 9 and below the second electromagnetic valve 16, and a three-way joint 14 is arranged in the connecting groove 6, one end of the second electromagnetic valve 16 is connected with one end of the three-way joint 14, one end of the first electromagnetic valve 15 is connected with the other end of the three-way joint 14, a first hose 23 is arranged inside the connecting groove 6, a third electromagnetic valve 24 is arranged on one side of the piston cylinder 9 and below the first electromagnetic valve 15, a fourth electromagnetic valve 25 is arranged on one side of the piston cylinder 9 and below the third electromagnetic valve 24, the third electromagnetic valve 24 and the fourth electromagnetic valve 25 are both connected with one end of the first hose 23, the bottom end of the first hose 23 extends into the base 1, one end of the return spring 12 is connected with one end of the push plate 11, and the other end of the return spring 12 is connected with one side of the piston cylinder 9.

A fixed groove 17 for storing the second hose 26 is formed in the top plate 3 and located at one side of the connecting groove 6, a connecting plate 38 is arranged in an inner cavity of the fixed groove 17, a pipe roller 19 for winding the second hose 26 is rotatably connected to the top of the connecting plate 38, the second hose 26 is wound on the outer side of the pipe roller 19, a connecting pipe 20 is arranged in the pipe roller 19, one end of the second hose 26 is connected to one end of the connecting pipe 20, a rotary joint 21 is arranged at the bottom of the connecting plate 38, the top end of the rotary joint 21 is connected to one end of the connecting pipe 20, a fixed pipe 22 is arranged at the bottom end of the rotary joint 21, one end of the fixed pipe 22 extends into the connecting groove 6 and is connected to the remaining end of the three-way joint 14, one end of the second hose 26 extends to the outer side of the top plate 3 and is provided with a water head, the water head is taken out from a nearby water body or a carried water tank, and then the output end of the first servo motor 18 drives the pipe roller 19 to rotate reversely, the second hose 26 is wound on the outer side of the tube roller 19, the top of the top plate 3 is provided with a first servo motor 18 for driving the tube roller 19 to rotate, the output end of the first servo motor 18 is connected with the top end of the tube roller 19, so that the output end of the first servo motor 18 can drive the tube roller 19 to rotate, the bottom of the top plate 3 is provided with a second servo motor 37 for driving the rotating rod 7 to rotate, the output end of the second servo motor 37 is connected with the bottom end of the rotating rod 7, so that the output end of the second servo motor 37 can drive the rotating rod 7 to rotate, the storage chamber 5 is arranged in the storage tank 4, the inner cavity of the storage chamber 5 is rotatably connected with two threaded rods 33, the outer side of each threaded rod 33 is in threaded connection with a moving block 34, a monitoring mechanism 35 is arranged between the two moving blocks 34, the monitoring mechanism 35 is conveniently driven to move, and the storage chamber 5 is arranged in the storage tank 4, the inside transmission groove 30 that has seted up that just is located the below of storage chamber 5 of storage box 4, the top of dwang 7 extends to inside and the cover of transmission groove 30 and is equipped with second bevel gear 29, the top of transmission groove 30 inner chamber and the both sides that are located dwang 7 all are provided with connecting block 39, one side of connecting block 39 all rotates and is connected with axis of rotation 27, the one end of axis of rotation 27 all overlaps and is equipped with first bevel gear 28, first bevel gear 28 all is connected with second bevel gear 29 meshing, the other end of axis of rotation 27 all extends to one side of connecting block 39 and is equipped with fourth bevel gear 32, the bottom of threaded rod 33 all extends to inside and the cover of transmission groove 30 and is equipped with third bevel gear 31, third bevel gear 31 all is connected with fourth bevel gear 32 meshing, dwang 7 rotates and can drive threaded rod 33 and rotate, the top of monitoring mechanism 35 is located the top of storage box 4 and is provided with baffle 36, second solenoid valve 16, the cover is equipped with third bevel gear 31, One ends of the first electromagnetic valve 15, the fourth electromagnetic valve 25 and the third electromagnetic valve 24, which are located in the inner cavity of the piston cylinder 9, are all provided with one-way valves, so that water can be drained or pumped from the interior of the base 1.

In conclusion, when the ecological environment monitoring device is used, an operator places the base 1 on the ground, then starts the electric telescopic rod 2, so that the telescopic end of the electric telescopic rod 2 pushes the top plate 3 to move upwards, then starts the first servo motor 18, so that the output end of the first servo motor 18 drives the tube roller 19 to rotate, so that the second hose 26 is discharged, so that the operator can pull out the second hose 26, place a water head into a nearby water body or a carried water tank, at this time, the first electromagnetic valve 15 and the third electromagnetic valve 24 are opened, then the output end of the second servo motor 37 drives the rotating rod 7 to rotate, so that the cam 8 rotates, so that the round end of the cam 8 rotates towards the push plate 11, so that the return spring 12 pushes the push plate 11 to move towards the cam 8, so that water enters the second hose 26 through the suction head, and then enters the fixed tube 22 through the rotary joint 21, then enters the piston cylinder 9 through the first electromagnetic valve 15, the convex end of the cam 8 rotates towards the push plate 11, so that the push plate 11 pushes the piston rod 10 to move to return, so that the piston block 13 moves to return, so that the water in the piston cylinder 9 enters the first hose 23 through the third electromagnetic valve 24, so that the weight of the base 1 is increased, the rotating rod 7 rotates to drive the second bevel gear 29 to rotate, so that the first bevel gear 28 rotates, so that the rotating shaft 27 rotates, at this time, the fourth bevel gear 32 drives the third bevel gear 31 to rotate, so that the threaded rod 33 rotates, so that the moving block 34 drives the monitoring mechanism 35 to move upwards, so that the monitoring mechanism 35 moves to the upper part of the storage box 4 to work, when the monitoring mechanism 35 moves to the working position, the water in the base 1 is filled, then the water head is taken out from the nearby water body or the carried water tank, and then the output end of the first servo motor 18 drives the pipe roller 19 to rotate reversely, so that the second hose 26 is wound on the outside of the tube roll 19;

when the device needs to be moved, an operator starts the first servo motor 18 to enable the output end of the first servo motor 18 to drive the tube roller 19 to rotate, the second hose 26 is discharged, the operator can pull out the second hose 26 to place a water head into a nearby water body or a carried water tank, at the moment, the first electromagnetic valve 15 and the third electromagnetic valve 24 are closed, the second electromagnetic valve 16 and the fourth electromagnetic valve 25 are opened, then the output end of the second servo motor 37 drives the rotating rod 7 to rotate, the cam 8 rotates in the reverse direction, the round end of the cam 8 rotates towards the push plate 11, the reset spring 12 pushes the push plate 11 to move towards the cam 8, water enters the fourth electromagnetic valve 25 through the first hose 23 and then enters the piston cylinder 9 through the fourth electromagnetic valve 25, and the convex end of the cam 8 rotates towards the push plate 11, so that the push plate 11 pushes the piston rod 10 to move in a resetting way, the piston block 13 moves in a resetting way, water in the piston cylinder 9 enters the fixed pipe 22 through the second electromagnetic valve 16, enters the second hose 26 through the rotary joint 21, is discharged into a water body or a carried water tank through a water head, the weight of the base 1 is reduced, the rotating rod 7 rotates to drive the second bevel gear 29 to rotate in a reverse direction, the first bevel gear 28 rotates in a reverse direction, the rotating shaft 27 rotates in a reverse direction, the fourth bevel gear 32 drives the third bevel gear 31 to rotate in a reverse direction at the moment, the threaded rod 33 rotates in a reverse direction, the moving block 34 drives the monitoring mechanism 35 to move downwards, the monitoring mechanism 35 moves into the storage cavity 5, when the bottom of the baffle plate 36 is in contact with the top of the storage tank 4, water in the base 1 is discharged, and then the water head is taken out of the water body or the carried water tank nearby, then the output end of the first servo motor 18 drives the tube roller 19 to rotate reversely, so that the second hose 26 is wound on the outer side of the tube roller 19, and then the telescopic end of the electric telescopic rod 2 drives the top plate 3 to descend, and an operator can move the device conveniently.

The above description is only for the preferred embodiment 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 technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (7)

1. The utility model provides an ecological environment monitoring devices, includes base (1), its characterized in that: the top of the base (1) is provided with two electric telescopic rods (2), the telescopic ends of the electric telescopic rods (2) are provided with a top plate (3), the top of the top plate (3) is fixedly provided with a storage box (4), a connecting groove (6) is formed in the top plate (3), the bottom of the inner cavity of the connecting groove (6) is rotatably connected with a rotating rod (7), the outer side of the rotating rod (7) is sleeved with a cam (8), a piston cylinder (9) is fixedly arranged in the connecting groove (6), a piston block (13) is slidably connected in the piston cylinder (9), one end of the piston block (13) is provided with a piston rod (10), the other end of the piston rod (10) extends to the outer side of the piston cylinder (9) and is provided with a push plate (11), the outer side of the piston rod (10) is sleeved with a return spring (12), one side of the piston cylinder (9) is provided with a second electromagnetic valve (16), a first electromagnetic valve (15) is arranged on one side of the piston cylinder (9) and below the second electromagnetic valve (16), a three-way joint (14) is arranged in the connecting groove (6), one end of the second electromagnetic valve (16) is connected with one end of the three-way joint (14), one end of the first electromagnetic valve (15) is connected with the other end of the three-way joint (14), a first hose (23) is arranged in the connecting groove (6), a third electromagnetic valve (24) is arranged on one side of the piston cylinder (9) and below the first electromagnetic valve (15), a fourth electromagnetic valve (25) is arranged on one side of the piston cylinder (9) and below the third electromagnetic valve (24), the third electromagnetic valve (24) and the fourth electromagnetic valve (25) are connected with one end of the first hose (23), and the bottom end of the first hose (23) extends into the base (1).

2. The ecological environment monitoring device of claim 1, characterized in that: fixed slot (17) have been seted up to roof (3) inside and one side that is located spread groove (6), fixed slot (17) inner chamber is provided with connecting plate (38), the top of connecting plate (38) is rotated and is connected with pipe roller (19), the outside winding of pipe roller (19) has second hose (26), pipe roller (19) inside is provided with connecting pipe (20), the one end of second hose (26) is connected with the one end of connecting pipe (20), the bottom of connecting plate (38) is provided with rotary joint (21), the top of rotary joint (21) is connected with the one end of connecting pipe (20), the bottom of rotary joint (21) is provided with fixed pipe (22), the one end of fixed pipe (22) extends to spread groove (6) inside and is connected with the surplus one end of three way connection (14).

3. The ecological environment monitoring device of claim 1, characterized in that: the top of roof (3) is provided with first servo motor (18), the output of first servo motor (18) is connected with the top of pipe roller (19).

4. The ecological environment monitoring device of claim 1, characterized in that: the bottom of roof (3) is provided with second servo motor (37), the output of second servo motor (37) is connected with the bottom of dwang (7).

5. The ecological environment monitoring device of claim 1, characterized in that: storage chamber (5) have been seted up to the inside of storage box (4), storage chamber (5) inner chamber rotates and is connected with two threaded rods (33), the equal threaded connection in outside of threaded rod (33) has movable block (34), two be provided with monitoring mechanism (35) between movable block (34).

6. The ecological environment monitoring device of claim 5, wherein: the storage box (4) is internally provided with a storage cavity (5), the storage box (4) is internally provided with a transmission groove (30) below the storage cavity (5), the top end of the rotating rod (7) extends to the inside of the transmission groove (30) and is sleeved with a second bevel gear (29), the top of the inner cavity of the transmission groove (30) and the two sides of the rotating rod (7) are respectively provided with a connecting block (39), one side of each connecting block (39) is rotatably connected with a rotating shaft (27), one end of each rotating shaft (27) is sleeved with a first bevel gear (28), the first bevel gears (28) are respectively meshed with the second bevel gears (29), the other end of each rotating shaft (27) extends to one side of the connecting block (39) and is sleeved with a fourth bevel gear (32), the bottom end of each threaded rod (33) extends to the inside of the transmission groove (30) and is sleeved with a third bevel gear (31), the third bevel gears (31) are in meshed connection with the fourth bevel gears (32).

7. The ecological environment monitoring device of claim 5, wherein: and a baffle (36) is arranged at the top of the monitoring mechanism (35) and above the storage box (4).

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