CN115435205A

CN115435205A - Underground water level monitoring device

Info

Publication number: CN115435205A
Application number: CN202211401864.5A
Authority: CN
Inventors: 郝杰; 罗振江; 王琳; 王庆广; 袁辉; 高奎峰; 孟凡耀; 孙虹洁; 韩江雪
Original assignee: No 801 Hydrogeological Engineering Geology Brigade of Shandong Bureau of Geology and Mineral Resources
Current assignee: No 801 Hydrogeological Engineering Geology Brigade of Shandong Bureau of Geology and Mineral Resources
Priority date: 2022-11-10
Filing date: 2022-11-10
Publication date: 2022-12-06
Anticipated expiration: 2042-11-10
Also published as: CN115435205B

Abstract

The utility model relates to an underground water level monitoring device, which relates to the technical field of underground water monitoring and comprises a winch, a monitoring instrument body and a protection mechanism, wherein the protection mechanism comprises a connecting block, a protection block, a bottom plate and a first adjusting component; the bottom plate is arranged on the protection block through the first adjusting component and can cover the placing groove. The method and the device have the effect of reducing the phenomenon that the monitoring effect is weakened.

Description

Underground water level monitoring device

Technical Field

The application relates to the technical field of underground water monitoring, in particular to an underground water level monitoring device.

Background

Among the prior art, traditional ground water level monitoring device uses the rope to send supervisory equipment into the well usually, monitors ground water level, and when transferring supervisory equipment, supervisory equipment rocks easily, leads to supervisory equipment and the wall of a well to bump mutually, and supervisory equipment damages easily to cause the monitoring effect weak.

Disclosure of Invention

In order to reduce the phenomenon that the monitoring effect is weakened, the application provides a groundwater level monitoring device.

The application provides an underground water level monitoring device adopts following technical scheme:

the underground water level monitoring device comprises a winch, a monitoring instrument body and a protection mechanism, wherein the protection mechanism comprises a connecting block, a protection block, a bottom plate and a first adjusting assembly, the connecting block is arranged on a connecting rope of the winch, the protection block is arranged on the connecting block, a placing groove is formed in the protection block, one end, far away from the winch, of the connecting block is located in the placing groove, and the monitoring instrument body is arranged on the connecting block located in the placing groove; the bottom plate is arranged on the protection block through the first adjusting component and can cover the placing groove.

By adopting the technical scheme, when underground water needs to be monitored, a down-the-hole is firstly drilled, then the protection block and the connecting block are placed in the down-the-hole, then the winch is started, the connecting rope on the winch drives the connecting block to move, the connecting block drives the protection block to move, the monitor body is moved to a proper position, then the first adjusting assembly is started, the first adjusting assembly drives the bottom plate to move, the bottom plate does not cover the placing groove any more, and the monitor body in the placing groove can monitor the underground water; the protection machanism who sets up can be when moving the suitable position in underground with the control appearance body to reduce colliding with of control appearance body, thereby reduce the phenomenon that monitoring effect weakens.

Optionally, the first adjusting assembly includes a first motor and a first rotating shaft, the first motor is disposed on the protective block, the first rotating shaft is rotatably disposed on an output shaft of the first motor, and the bottom plate is disposed on the first rotating shaft.

Through adopting above-mentioned technical scheme, the output shaft of first motor drives first pivot and rotates, and first pivot will drive the bottom plate motion.

Optionally, a lifting assembly is arranged on the connecting block, the lifting assembly includes a sliding block, a second motor and a screw rod, a through hole communicated with the placing groove is formed in the protective block, the connecting block passes through the through hole, a first sliding groove is formed in the connecting block, the sliding block is slidably arranged in the first sliding groove, and the sliding block is arranged on the protective block; the screw rod is rotatably arranged in the first sliding groove, penetrates through the sliding block and is in threaded connection with the sliding block; the second motor is arranged on the connecting block, and the screw is connected with an output shaft of the second motor.

Through adopting above-mentioned technical scheme, when the control groundwater that is better for making the control appearance body, the output shaft for the motor drives the screw rod and rotates, and the screw rod drives the slider and slides in first spout, and the slider will drive the relative connecting block of protection piece and take place relative motion, makes the control appearance body no longer be located the standing groove, can make the better control groundwater of control appearance body.

Optionally, a safety mechanism is arranged on the connecting block, the safety mechanism includes two fixing blocks, a main rod, an auxiliary rod and a second adjusting assembly, and one fixing block is arranged on each of the connecting block and the bottom plate; the main rod is hinged to the fixing block of the connecting block, the auxiliary rod is arranged on the main rod in a sliding mode, and one end, far away from the main rod, of the auxiliary rod is hinged to the fixing block of the bottom plate; the second adjusting component is arranged on the main rod and connected with the auxiliary rod.

Through adopting above-mentioned technical scheme, when the output shaft of first motor damaged but output shaft normal pivoted, start the second adjusting part, the second adjusting part can drive vice pole and slide on the mobile jib, and the position of the relative mobile jib of vice pole will change, and vice pole will promote the bottom plate motion, makes the position of bottom plate can change.

Optionally, the second adjusting assembly includes a first rack, a first gear and a third motor, and the first rack is disposed on the secondary rod; the third motor is arranged on the main rod, and the first gear is arranged on an output shaft of the third motor and meshed with the first gear.

Through adopting above-mentioned technical scheme, the output shaft of third motor drives first gear revolve, and the first rack with first gear engagement will drive the secondary lever and move on the mobile jib.

Optionally, a position adjusting mechanism is arranged on the protective block, the position adjusting mechanism includes an electric pushing cylinder, a protective frame and a guide block, the electric pushing cylinder is arranged on the connecting block, the protective frame is arranged on a piston rod of the electric pushing cylinder, and the monitor body is arranged in the protective frame; the guide block is arranged on the side wall of the protective frame; the side wall of the placing groove is provided with a second sliding groove which is arranged in a sliding manner with the guide block, the bottom plate is provided with a third sliding groove which is arranged in a sliding manner with the guide block, and the third sliding groove can be communicated with the second sliding groove.

By adopting the technical scheme, when the second motor is damaged, the position of the bottom plate is firstly adjusted by the safety mechanism, so that the bottom plate is parallel to the protection block; then start the electric push cylinder, the piston rod of electric push cylinder drives the motion of protective frame, and the guide block on the protective frame moves to the third spout from the second spout to the messenger is located the control appearance body of protective frame and can moves out the standing groove.

Optionally, a limiting mechanism is arranged on the protection block, the limiting mechanism comprises a limiting rod, a limiting block, a second rack, a second rotating shaft, a second gear, a third gear and a third rack,

a fourth sliding groove is formed in the protection block, and the limiting rod is arranged in the fourth sliding groove in a sliding mode; the limiting block is arranged on the bottom plate, and a limiting hole clamped with the limiting rod is formed in the limiting block; the second rack is arranged on the guide block, the second rotating shaft is rotationally arranged on the protection block, and the second gear is connected with the second rotating shaft in a key manner and is meshed with the second rack; the third gear is connected to the second rotating shaft in a keyed mode, and the third rack is arranged on the limiting rod and meshed with the third gear.

By adopting the technical scheme, when the second motor is damaged and the position of the bottom plate is adjusted by the safety mechanism, the bottom plate cannot be better parallel to the protective block because the main rod and the auxiliary rod are hinged with the fixed block, but the guide block can better slide into the third chute from the second chute, so that the second rack on the guide block drives the second gear to rotate, the second gear drives the second rotating shaft to rotate, the third gear on the second rotating shaft drives the third gear to rotate, and the third rack meshed with the third gear drives the limiting rod to move; when the guide block moves to a position where the second chute is close to the third chute, the limiting rod can extend out of the protective block; when the guide block moves to the position where the second sliding groove is close to the third sliding groove, the protection frame can abut against the bottom plate, so that the bottom plate moves towards the direction close to the limiting rod and abuts against the limiting rod, and the bottom plate can be parallel to the protection block and slides into the third sliding groove from the second sliding groove in the guide block; when the guide block slides into the third sliding groove, the limiting rod can continue to move towards the direction close to the limiting block, so that the limiting rod enters the limiting hole of the limiting block.

Optionally, a pushing mechanism is arranged on the protection block, the pushing mechanism includes a fourth motor, a third rotating shaft and a pushing plate, the third rotating shaft is arranged on the protection block, and the third rotating shaft is arranged on an output shaft of the fourth motor and is perpendicular to the output shaft; the pushing plate is arranged on the third rotating shaft.

By adopting the technical scheme, when the protection block moves towards the underground water in the lower down-the-hole, the protection block can be blocked by the submergence Kong Tuleng, at the moment, the fourth motor is started, the output shaft of the fourth motor drives the third rotating shaft to rotate, the third rotating shaft drives the pushing plate to move, the pushing plate can abut against the side wall of the lower down-the-hole, the protection block is far away from the convex edge of the lower down-the-hole, and therefore the protection block can continuously slide downwards in the lower down-the-hole.

In summary, the invention includes at least one of the following beneficial technical effects:

1. through protection machanism's setting, can reduce the direct probability that takes place to collide with the wall of a well of monitoring appearance body when moving the suitable position in underground with the monitoring appearance body to the phenomenon of monitoring effect weak has been alleviateed.

2. Through the setting of safety mechanism, the output shaft of first motor damages but when the output shaft normally rotates, starts second adjusting part, and second adjusting part can drive the auxiliary rod and slide on the mobile jib, and the position of the relative mobile jib of auxiliary rod will change, and the auxiliary rod will promote the bottom plate motion, makes the position of bottom plate can change, so alright make the monitor body normally shift out from the protection piece to ground water level's detection is convenient for.

3. Through the setting of pushing mechanism, when the protection piece is at the time of the downthehole motion towards the groundwater in the downthehole, the protection piece can be stopped by some and dive Kong Tuleng, at this moment start the fourth motor, the output shaft of fourth motor drives the third pivot and rotates, the third pivot will drive the slurcam motion, the slurcam can support the lateral wall of the downthehole, make the protection piece keep away from the bead of downthehole down to make the protection piece can continue gliding in the downthehole down.

Drawings

FIG. 1 is a schematic diagram of the structure of a ground water level monitoring apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a lifting assembly in an embodiment of the present application;

FIG. 3 is a schematic structural diagram of a safety mechanism according to an embodiment of the present application;

fig. 4 is a schematic structural diagram of a position adjustment mechanism in an embodiment of the present application.

Reference numerals: 11. a winch; 12. a monitor body; 2. a protection mechanism; 21. connecting blocks; 22. a protection block; 221. a placement groove; 23. a base plate; 231. a third chute; 24. a first adjustment assembly; 241. a first motor; 242. a first rotating shaft; 25. a lifting assembly; 251. a slider; 252. a second motor; 253. a screw; 3. a safety mechanism; 31. a fixed block; 32. a main rod; 33. an auxiliary rod; 34. a second adjustment assembly; 341. a first rack; 342. a first gear; 343. a third motor; 4. a position adjustment mechanism; 41. an electric pushing cylinder; 42. a protective frame; 43. a guide block; 44. a connecting frame; 5. a limiting mechanism; 51. a restraining bar; 52. a limiting block; 53. a second rack; 54. a second rotating shaft; 55. a second gear; 56. a third gear; 57. a third rack; 6. a pushing mechanism; 61. a fourth motor; 62. a third rotating shaft; 63. and pushing the plate.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses groundwater level monitoring device.

Referring to fig. 1, the ground water level monitoring apparatus includes a hoist 11, and a protection mechanism 2 is connected to a connection rope of the hoist 11.

Referring to fig. 1 and 2, the protection mechanism 2 includes a connection block 21 connected to a connection rope on the winch 11, a protection block 22 is disposed on the connection block 21, a placement groove 221 is disposed on the protection block 22, and a water inlet hole communicated with the placement groove 221 is disposed on the protection block 22; the outer side wall of the protection block 22 is fixedly connected with a protection sleeve.

A through hole communicated with the placing groove 221 is formed in the protection block 22, and one end, far away from the connecting rope, of the connecting block 21 penetrates through the through hole; the connecting block 21 is provided with a first sliding groove. The connecting block 21 is provided with a lifting component 25, the lifting component 25 comprises a sliding block 251 connected in the first sliding groove in a sliding manner, and the sliding block 251 is fixedly connected with the protection block 22; a screw 253 is rotatably connected in the first sliding groove, and the screw 253 passes through the sliding block 251 and is in threaded connection with the sliding block 251; a second motor 252 is fixedly connected to the connecting block 21, and an output shaft of the second motor 252 is connected to one end of a screw 253.

When the second motor 252 is started, the output shaft of the second motor 252 drives the screw 253 to rotate, the screw 253 drives the sliding block 251 to slide in the first sliding groove, and when the sliding block 251 moves, the sliding block 251 drives the protection block 22 to move relative to the connection block 21.

Referring to fig. 2 and 3, a bottom plate 23 is arranged at one end of the protection block 22 away from the connection block 21, a first adjusting assembly 24 is arranged on the protection block 22, the first adjusting assembly 24 includes a first motor 241 fixedly connected to the protection block 22, a first rotating shaft 242 is connected to an output shaft of the first motor 241, and the bottom plate 23 is fixedly connected to the first rotating shaft 242.

When the first motor 241 is started, the output shaft of the first motor 241 drives the bottom plate 23 to move, so that the bottom plate 23 covers the placing groove 221.

Referring to fig. 2 and 4, the connecting block 21 is provided with a safety mechanism 3, the safety mechanism 3 includes two fixing blocks 31, one fixing block 31 is fixed on the connecting block 21, and the other fixing block 31 is fixed on one side of the bottom plate 23 facing the connecting block 21; a main rod 32 is hinged on a fixed block 31 of the connecting block 21, a groove is formed in the main rod 32 along the length direction of the main rod, an auxiliary rod 33 is connected in the groove in a sliding mode, and one end, far away from the connecting block 21, of the auxiliary rod 33 is hinged on the fixed block 31 located on the bottom plate 23. The main rod 32 is provided with a second adjusting assembly 34, the second adjusting assembly 34 comprises a third motor 343 fixedly connected to the main rod 32, and an output shaft of the third motor 343 is in keyed connection with a first gear 342; a first rack 341 engaged with the first gear 342 is fixedly connected to the sub-lever 33.

When the output shaft of the first motor 241 is damaged but normally rotates, the third motor 343 is started, the output shaft of the third motor 343 drives the first gear 342 to rotate, the first gear 342 drives the first rack 341 to move, the first rack 341 drives the auxiliary rod 33 to slide in the groove of the main rod 32, the position of the auxiliary rod 33 relative to the main rod 32 changes, the auxiliary rod 33 pushes the bottom plate 23 to move, and the position of the bottom plate 23 can change.

Referring to fig. 2 and 4, a second sliding groove is formed in a side wall of the placing groove 221, a third sliding groove 231 communicated with the second sliding groove is formed in the bottom plate 23, a position adjusting mechanism 4 is arranged on the protection block 22, the position adjusting mechanism 4 includes an electric pushing cylinder 41 fixedly connected to the connecting block 21, a connecting frame 44 is connected to a piston rod of the electric pushing cylinder 41, a protection frame 42 is connected to the connecting frame 44, and the monitor body 12 is placed in the protection frame 42; fixedly connected with guide block 43 on the lateral wall of protective frame 42, second spout and third spout 231 all can slide the setting with guide block 43.

When the monitoring instrument body 12 needs to be adjusted, the electric pushing cylinder 41 is started, the connecting frame 44 on the piston rod of the electric pushing cylinder 41 drives the protecting frame 42 to move, the guide block 43 on the protecting frame 42 can slide into the third sliding groove 231 from the second sliding groove, and the monitoring instrument body 12 moves out of the placing groove 221 of the protecting block 22.

Referring to fig. 2 and 4, the protection block 22 is provided with a limiting mechanism 5, a fourth sliding groove is formed in the outer side wall of the protection block 22, and the limiting mechanism 5 comprises a limiting rod 51 connected in the fourth sliding groove in a sliding manner; a limiting block 52 is fixedly connected to one side of the bottom plate 23 far away from the fixing block 31, and a limiting hole clamped with the limiting rod 51 is formed in the limiting block 52; a second rack 53 is fixedly connected to the guide block 43, a second rotating shaft 54 is rotatably connected to the protection block 22, one end of the second rotating shaft 54 is located in the placing groove 221, the other end of the second rotating shaft 54 is located outside the protection block 22, and a second gear 55 meshed with the second rack 53 is connected to the second rotating shaft 54 located in the placing groove 221 in a key manner; a third gear 56 is keyed on the second rotating shaft 54 at one end far away from the second gear 55, and a second rack 53 engaged with the second gear 55 is fixedly connected on the limiting rod 51.

When the guide block 43 slides in the second sliding slot, the second rack 53 on the guide block 43 drives the second gear 55 to rotate, the second gear 55 drives the second rotating shaft 54 to rotate, the second rotating shaft 54 drives the third gear 56 to rotate, the third gear 56 drives the third rack 57 to move, and the third rack 57 drives the limiting rod 51 to move, so that the limiting rod 51 moves towards the direction close to the limiting block 52 and extends into the limiting hole of the limiting block 52.

Referring to fig. 1 and 2, the protection block 22 is provided with a pushing mechanism 6, the pushing mechanism 6 includes a fourth motor 61 fixedly connected to the protection block 22, an output shaft of the fourth motor 61 is connected to a third rotating shaft 62, the third rotating shaft 62 is perpendicular to the output shaft of the fourth motor 61, and the third rotating shaft 62 is fixedly connected to a pushing plate 63.

The implementation principle of the underground water level monitoring device provided by the embodiment of the application is as follows: firstly, punching a submergence hole communicated with underground water on the ground; then, the connecting block 21 and the protection block 22 are placed in the submergence hole, and the winch 11 is placed on the ground; then, the winch 11 is started as required, and the winch 11 drives the connecting block 21 to change in position, so that the connecting block 21 moves to a proper position.

The second motor 252 is started, the output shaft of the second motor 252 drives the screw 253 to rotate, the screw 253 drives the sliding block 251 to slide in the first sliding groove, and the sliding block 251 drives the protection block 22 to move, so that the protection block 22 moves in a direction away from the monitor body 12; when the protection block 22 moves, the guide block 43 slides in the second sliding groove, the second rack 53 on the guide block 43 drives the second gear 55 to rotate, the second gear 55 drives the second rotating shaft 54 to rotate, the second rotating shaft 54 drives the third gear 56 to rotate, the third gear 56 drives the third rack 57 to move, the third rack 57 drives the limiting rod 51 to move, but the limiting rod 51 does not extend into the limiting hole of the limiting block 52.

Then, the first motor 241 and the third motor 343 are started, the output shaft of the first motor 241 drives the first rotating shaft 242 to rotate, and the first rotating shaft 242 drives the bottom plate 23 to move; an output shaft of the third motor 343 drives the first gear 342 to rotate, the first gear 342 drives the first rack 341 to move, the first rack 341 drives the auxiliary rod 33 to slide in the groove of the main rod 32, the position of the auxiliary rod 33 relative to the main rod 32 changes, and the auxiliary rod 33 pushes the bottom plate 23 to move; so that the bottom plate 23 no longer covers the placing groove 221 and the bottom plate 23 is parallel to the placing block.

The electric pushing cylinder 41 is started, the piston rod of the electric pushing cylinder 41 drives the protection frame 42 to move, the guide block 43 on the protection frame 42 can slide into the third sliding groove 231 of the bottom plate 23 from the second sliding groove of the protection block 22, so that the protection frame 42 is no longer positioned in the placing groove 221, and the monitoring instrument body 12 can monitor the underground water conveniently; and the restricting rod 51 protrudes into the restricting hole of the restricting block 52.

When the protection block 22 is blocked by some submarine Kong Tuleng, the fourth motor 61 is started, the output shaft of the fourth motor 61 drives the third rotating shaft 62 to rotate, the third rotating shaft 62 drives the pushing plate 63 to move, the pushing plate 63 abuts against the side wall of the submarine hole, the protection block 22 is far away from the rib of the submarine hole, and therefore the protection block 22 can continuously slide downwards in the submarine hole.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims

1. The underground water level monitoring device comprises a winch (11) and a monitoring instrument body (12), and is characterized by further comprising a protection mechanism (2), wherein the protection mechanism (2) comprises a connecting block (21), a protection block (22), a bottom plate (23) and a first adjusting component (24), the connecting block (21) is arranged on a connecting rope of the winch (11), the protection block (22) is arranged on the connecting block (21), a placing groove (221) is formed in the protection block (22), one end, far away from the winch (11), of the connecting block (21) is located in the placing groove (221), and the monitoring instrument body (12) is arranged on the connecting block (21) located in the placing groove (221); the bottom plate (23) is arranged on the protection block (22) through the first adjusting component (24) and can cover the placing groove (221).

2. An underground water level monitoring apparatus according to claim 1,

the first adjusting assembly (24) comprises a first motor (241) and a first rotating shaft (242), the first motor (241) is arranged on the protective block (22), the first rotating shaft (242) is rotatably arranged on an output shaft of the first motor (241), and the base plate (23) is arranged on the first rotating shaft (242).

3. The underground water level monitoring device according to claim 1, wherein a lifting assembly (25) is arranged on the connecting block (21), the lifting assembly (25) comprises a sliding block (251), a second motor (252) and a screw rod (253), a through hole communicated with the placing groove (221) is formed in the protecting block (22), the connecting block (21) penetrates through the through hole, a first sliding groove is formed in the connecting block (21), the sliding block (251) is arranged in the first sliding groove in a sliding manner, and the sliding block (251) is arranged on the protecting block (22);

the screw rod (253) is rotatably arranged in the first sliding groove, and the screw rod (253) penetrates through the sliding block (251) and is in threaded connection with the sliding block (251);

the second motor (252) is arranged on the connecting block (21), and the screw (253) is connected with an output shaft of the second motor (252).

4. A ground water level monitoring device according to claim 1, characterized in that a safety mechanism (3) is arranged on the connecting block (21), the safety mechanism (3) comprises a fixed block (31), a main rod (32), an auxiliary rod (33) and a second adjusting component (34), two fixed blocks (31) are arranged, and one fixed block (31) is arranged on each of the connecting block (21) and the bottom plate (23);

the main rod (32) is hinged to the fixing block (31) of the connecting block (21), the auxiliary rod (33) is arranged on the main rod (32) in a sliding mode, and one end, far away from the main rod (32), of the auxiliary rod (33) is hinged to the fixing block (31) of the bottom plate (23);

the second adjusting assembly (34) is arranged on the main rod (32) and connected with the auxiliary rod (33).

5. A groundwater level monitoring device according to claim 4, characterized in that the second adjustment assembly (34) comprises a first rack (341), a first gear wheel (342) and a third motor (343), the first rack (341) being arranged on the secondary lever (33); the third motor (343) is provided on the main lever (32), and the first gear (342) is provided on an output shaft of the third motor (343) and is meshed with the first gear (342).

6. The underground water level monitoring device according to claim 4, wherein a position adjusting mechanism (4) is arranged on the protection block (22), the position adjusting mechanism (4) comprises an electric pushing cylinder (41), a protection frame (42) and a guide block (43), the electric pushing cylinder (41) is arranged on the connecting block (21), the protection frame (42) is arranged on a piston rod of the electric pushing cylinder (41), and the monitor body (12) is arranged in the protection frame (42);

the guide block (43) is arranged on the side wall of the protective frame (42);

the side wall of the placing groove (221) is provided with a second sliding groove which is arranged in a sliding manner with the guide block (43), the bottom plate (23) is provided with a third sliding groove (231) which is arranged in a sliding manner with the guide block (43), and the third sliding groove (231) can be communicated with the second sliding groove.

7. A groundwater level monitoring device according to claim 6, characterised in that a limiting mechanism (5) is arranged on the protection block (22), the limiting mechanism (5) comprising a limiting rod (51), a limiting block (52), a second gear rack (53), a second rotating shaft (54), a second gear wheel (55), a third gear wheel (56) and a third gear rack (57),

a fourth sliding groove is formed in the protection block (22), and the limiting rod (51) is arranged in the fourth sliding groove in a sliding mode; the limiting block (52) is arranged on the bottom plate (23), and a limiting hole clamped with the limiting rod (51) is formed in the limiting block (52);

the second rack (53) is arranged on the guide block (43),

the second rotating shaft (54) is rotationally arranged on the protective block (22), and the second gear (55) is connected with the second rotating shaft (54) in a key mode and is meshed with the second rack (53);

the third gear (56) is connected with the second rotating shaft (54) in a key mode, and the third rack (57) is arranged on the limiting rod (51) and meshed with the third gear (56).

8. A ground water level monitoring device according to claim 1, characterized in that a pushing mechanism (6) is arranged on the protection block (22), the pushing mechanism (6) comprises a fourth motor (61), a third rotating shaft (62) and a pushing plate (63), the third rotating shaft (62) is arranged on the protection block (22), the third rotating shaft (62) is arranged on an output shaft of the fourth motor (61) and is perpendicular to the output shaft;

the pushing plate (63) is arranged on the third rotating shaft (62).