CN117871186A

CN117871186A - Hydrogeological exploration groundwater level device and application method thereof

Info

Publication number: CN117871186A
Application number: CN202410269143.6A
Authority: CN
Inventors: 门兆龙; 鲁宁宁; 万豪豪; 王印慧; 桑胜萍
Original assignee: Shangdong Provincirl Bureru Of Corl Geology
Current assignee: Shangdong Provincirl Bureru Of Corl Geology
Priority date: 2024-03-11
Filing date: 2024-03-11
Publication date: 2024-04-12

Abstract

The invention relates to the technical field of geological exploration, in particular to a hydrogeological exploration groundwater level device and a using method thereof, the hydrogeological exploration groundwater level device comprises a first shell, wherein a storage wheel is arranged on one side of the first shell, a storage rope is fixedly connected between the storage wheel and the first shell, scale marks for detecting the pulled-out length of the storage rope by workers are arranged on the outer surface of the storage rope, three groups of sample mechanisms capable of collecting samples for different water levels are fixedly arranged on the upper end surface of a fixed plate, a floating block is fixedly connected to the bottom end of an abutting spring, a trigger block is fixedly connected to the upper end surface of the floating block, when the floating block contacts with the water surface, the spring is pressed by buoyancy and drives the trigger block to abut against an alarm, groundwater enters a first hole through a water inlet cavity, the groundwater can fall into a storage container through the first hole, and the second hole is the groundwater flows into a third hole, so that sampling of different water level depths can be realized, and the limitation that the traditional water level surveying device can only measure the water level is broken.

Description

Hydrogeological exploration groundwater level device and application method thereof

Technical Field

The invention relates to the technical field of geological exploration, in particular to a hydrogeological exploration groundwater level device and a use method thereof.

Background

Groundwater level is one of the important parameters in hydrogeology research, reflecting the abundance and distribution of groundwater. Accurately measuring the change of the groundwater level has important significance for water resource management, groundwater development and utilization and environmental protection, and besides the change of the water level, the chemical composition of the groundwater needs to be analyzed, because the relationship between the aggressiveness of the groundwater and the potential influence on a building is related, the conventional groundwater level observation method is that after the probe is penetrated into the ground, the depth is confirmed through the scale on the observation scale, and the groundwater composition cannot be detected, so that the limitation is imposed.

The invention provides a Chinese patent (bulletin No. CN 117191159A), which provides a hydrogeological exploration groundwater level observation device, comprising: the first support frame is provided with a support component which can stretch along the peripheral side, and a plurality of laser range finders are rotatably arranged below the first support frame; and a second support frame positioned below the first support frame, wherein the right side of the second support frame is provided with a walking assembly, a plurality of floating blocks are connected to the second support frame in a sliding manner along the vertical direction, and a plurality of laser range finders are arranged in one-to-one correspondence with the plurality of floating blocks. The invention can monitor the water level in real time, is suitable for the water level observation process of static water bodies and flowing water bodies, does not need the operation processes such as a scale and the like in the use process, avoids the manual error generated in the manual operation process, improves the water level monitoring precision, and has the advantages of wide application range, simple and convenient use process and the like.

When the scheme is used, the height of the groundwater level can be measured, and when the groundwater is surveyed, the water quality is detected by analyzing chemical components in a water layer, but the scheme can only detect the height of the water surface and can achieve more accurate effect and data, reduce measurement errors, and can not sample groundwater quality of different depths.

Disclosure of Invention

The invention aims to provide a hydrogeological exploration groundwater level device and a use method thereof, which are used for solving the problem that groundwater quality of different depths cannot be sampled in the prior art.

In order to achieve the above purpose, the present invention provides the following technical solutions:

the utility model provides a hydrogeological exploration groundwater level device, includes first casing, first casing one side is provided with accomodates the wheel, accomodate fixedly connected with between wheel and the first casing and accomodate the rope, just accomodate the rope surface and be equipped with the scale mark that supplies the staff to detect the length that accomodates the rope to be pulled out, first casing inner wall fixedly connected with is three sets of fixed plates, fixed plate up end fixed mounting has three sets of sample mechanisms that can collect the sample to different water levels, fixed plate bottom fixed mounting has three sets of storage mechanisms that can store the sample that sample mechanism collected, first casing bottom fixedly connected with second casing;

the crawling mechanism capable of controlling the second casing to move up and down is fixedly arranged in the second casing, the alarm and the abutting spring are fixedly arranged at the bottom of the second casing, the floating block is fixedly connected to the bottom end of the abutting spring, the triggering block is fixedly connected to the upper end of the floating block, and when the floating block contacts the water surface, the abutting spring is extruded through buoyancy and drives the triggering block to abut against the alarm, so that an alarm can be triggered to remind a worker of contacting the water surface.

As a still further scheme of the invention, the crawling mechanism comprises an electric telescopic arm, four groups of anti-skid tracks are arranged in the second machine shell, a plurality of crawler wheels are rotatably arranged on two sides of each anti-skid track, and the crawler wheels are connected with the electric telescopic arm through a shrinkage swing arm.

As still further scheme of the invention, the two ends of the contraction swing arm are respectively connected with the crawler wheel and the electric telescopic arm in a rotating way, the outer surfaces of every two groups of symmetrical contraction swing arms are abutted with the baffle posts, the outer surfaces of the electric telescopic arms are sleeved with the gas telescopic pipes, and the gas telescopic pipes are fixedly connected with the contraction swing arms.

As still further scheme of the invention, the sample mechanism comprises a water inlet cavity which is fixedly connected with the upper end of the fixed plate, and a water pressure block is connected in the water inlet cavity in a sliding way.

As a still further proposal of the invention, a hydraulic spring is fixedly connected between the hydraulic block and the inner wall of the water inlet cavity, and the three groups of fixing plates are provided with a first hole, a second hole and a third hole.

As still further scheme of the invention, the storage mechanism comprises a mounting plate, the mounting plate is in sliding connection with the inner wall of the first casing, the upper end surface of the mounting plate is fixedly connected with a connecting telescopic pipe with a resetting function, and the upper end surface of the connecting telescopic pipe is fixedly connected with a connecting plate.

As still further scheme of the invention, the mountain end face of the connecting plate is fixedly connected with a container fixing frame, the inner wall of the container fixing frame is clamped with a storage container for storing water samples, the bottom of the fixing plate is connected with a sliding plate in a sliding manner, a rotating arm is connected between the sliding plate and the connecting plate in a rotating manner, and one side of the mounting plate, which is close to the outer surface of the first shell, is fixedly connected with a magnetic door.

As a still further scheme of the invention, the two sides of the magnetic door are fixedly provided with powerful magnets, and one side of the magnetic door, which is abutted against the first shell, is fixedly connected with a waterproof rubber strip.

Compared with the prior art, the invention has the beneficial effects that:

1. when the first casing is submerged in the exploration well, the depth of the first casing is deeper, the water pressure born by the water pressure blocks is larger, the water pressure blocks can be pushed under the action of underground water pressure, when the three groups of water pressure blocks move under the action of water pressure, as the distance between the first hole and the outer surface of the first casing is shortest, the water pressure blocks of the group of the first hole reach and slide across the upper end surface of the first hole first, at the moment, underground water enters the first hole through the water inlet cavity and falls into the storage container through the first hole, when the first casing is submerged downwards, the underground water flows into the storage container through the second hole and the third hole in sequence, the principle is the same as the first hole, and the water level measuring device can realize sampling of different water level depths without redundant description, and breaks through the limitation that the traditional water level measuring device can only measure water levels.

2. When the underground water storage device is used, when the water in the storage container flows into the underground water, the storage container extrudes the connecting telescopic pipe, the connecting telescopic pipe is extruded and contracted, the connecting telescopic pipe is driven to move downwards when being contracted, the rotating arm is driven to move downwards when the connecting plate moves downwards, the rotating arm is driven to move downwards, the sliding plate is pulled to move downwards, the first hole can be blocked when the sliding plate moves, the first hole is prevented from continuously conveying the underground water into the storage container, sampling and storage of the underground water can be completed, the first hole, the second hole and the third hole are blocked in a gravity mode, electric operation is not needed, simplicity and convenience are realized, and faults are avoided.

Drawings

FIG. 1 is an elevation view of a hydrogeological groundwater level device and method of using the same.

FIG. 2 is a schematic cross-sectional view of a first housing of a hydrogeological water level device and method of use thereof.

FIG. 3 is a schematic illustration of the structure of the interior of a second housing of a hydrogeological apparatus and method of using the same.

FIG. 4 is a schematic diagram of a position structure of a contracting swing arm in a hydrogeological exploration groundwater level device and a method of using the same.

FIG. 5 is a schematic diagram of the location and structure of a storage vessel in a hydrogeological apparatus and method of use.

FIG. 6 is a schematic view of the internal structure of a connecting telescoping tube in a hydrogeological survey groundwater level device and method of using the same.

Fig. 7 is an enlarged view at a in fig. 5.

FIG. 8 is a schematic view of the position of a mounting plate in a hydrogeological survey groundwater level device and method of using the same.

FIG. 9 is a graph of the position of the first, second and third holes of a hydrogeological apparatus and method of using the same.

FIG. 10 is a schematic diagram of a hydrogeological groundwater level device and its connection pad position structure in a method of use.

FIG. 11 is a schematic view of the location of a mounting ring in a hydrogeological survey groundwater level device and method of use.

In the figure: 1. a storage wheel; 2. a storage rope; 3. a first housing; 4. a second housing; 5. a floating block; 6. an alarm; 7. abutting against the spring; 8. a trigger block; 9. an anti-skid track; 10. an electric telescopic arm; 11. a gas extension tube; 12. contracting the swing arm; 13. a rotating arm; 14. a connecting plate; 15. connecting the telescopic pipe; 16. a container holder; 17. a compression spring; 18. a storage container; 19. a first hole; 20. a fixing plate; 21. a first slide rail; 22. a slide plate; 23. a second slide rail; 24. a mounting plate; 25. a magnetic door; 26. a water pressure block; 27. a hydraulic spring; 28. a mounting ring; 29. a water inlet cavity; 30. a water inlet; 31. a paddle; 32. a spiral fan; 33. a connecting disc; 34. a water outlet; 35. a baffle column; 36. a second hole; 37. a third hole; 101. a crawling mechanism; 201. a storage mechanism; 301. a sample mechanism.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Embodiment one: referring to fig. 1, 2, 3, 4 and 9, in the embodiment of the invention, a hydrogeological exploration groundwater level device comprises a first casing 3, one side of the first casing 3 is provided with a storage wheel 1, a storage rope 2 is fixedly connected between the storage wheel 1 and the first casing 3, the outer surface of the storage rope 2 is provided with a scale mark for a worker to detect the pulled length of the storage rope 2, one side of the storage wheel 1 is fixedly connected with a rotating handle, the worker can conveniently rotate the storage wheel 1, three groups of fixing plates 20 are fixedly connected with the inner wall of the first casing 3, the three groups of fixing plates 20 are distributed circumferentially, three groups of sample mechanisms 301 capable of collecting samples at different water levels are fixedly arranged on the upper end surface of the fixing plates 20, three groups of storage mechanisms 201 capable of storing samples collected by the sample mechanisms 301 are fixedly arranged at the bottom end of the fixing plates 20, a crawling mechanism 101 capable of controlling the second casing 4 to move up and down is fixedly arranged inside the second casing 4, an alarm 6 and an abutting spring 7 are fixedly arranged at the bottom of the second casing 4, an end face of the abutting spring 7 is fixedly connected with a floating block 5, the end face 5 is fixedly connected with the floating block 5, and the floating block 5 is fixedly connected with the floating block 5 and can be abutted to the floating block 8 to the surface of the water surface by pressing the floating block 8 to trigger the alarm 7, and the floating block is contacted with the alarm 7 by the floating block and can be triggered by the pressing the floating block and contacted with the alarm 7.

Embodiment two: referring to fig. 1, 2 and 3, the crawling mechanism 101 includes an electric telescopic arm 10, four groups of anti-slip tracks 9 are disposed in the second housing 4, a plurality of track wheels are rotatably mounted on two sides of each anti-slip track 9, the track wheels are connected with the electric telescopic arm 10 through a shrinkage swing arm 12, a return spring is fixedly mounted in each shrinkage swing arm 12, the return spring can reset the shrinkage swing arm 12, two ends of each shrinkage swing arm 12 are respectively rotatably connected with the track wheels and the electric telescopic arm 10, the outer surfaces of every two groups of symmetrical shrinkage swing arms 12 are abutted with a baffle post 35, the outer surfaces of the baffle posts 35 are provided with arc surfaces, the outer surfaces of the electric telescopic arms 10 are sleeved with gas telescopic tubes 11, the gas telescopic tubes 11 are fixedly connected with the shrinkage swing arms 12, the gas telescopic tubes 11 are driven to shrink together when the electric telescopic arms 10 shrink, air in the gas telescopic tubes 11 can enter the inside the shrinkage swing arms 12, the shrinkage swing arms 12 are fully lengthened, the shrinkage swing arms 12 can increase the length of the shrinkage swing arms 12, the shrinkage swing arms 12 can abut against a exploration well with larger caliber, the outer surfaces of the baffle posts 35 are rubbed with the outer surfaces of the baffle posts 35, the baffle posts 35 are stretched, and the rubber telescopic tubes 12 are fixedly connected with the baffle posts 35 when the shrinkage swing arms 12 are stretched.

Referring to fig. 5, 7, 8 and 9, the sample mechanism 301 includes a water inlet cavity 29, the water inlet cavity 29 is fixedly connected to the upper end of the fixing plate 20, a water pressure block 26 is slidably connected to the inside of the water inlet cavity 29, a water pressure spring 27 is fixedly connected between the water pressure block 26 and the inner wall of the water inlet cavity 29, and the three groups of fixing plates 20 are provided with a first hole 19, a second hole 36 and a third hole 37.

Referring to fig. 5, 6, 7, 8, the storage mechanism 201 includes a mounting plate 24, the mounting plate 24 is slidably connected with an inner wall of the first casing 3, specifically, a second sliding rail 23 is disposed at an inner bottom end of the first casing 3, an outer surface of the second sliding rail 23 is slidably connected with the mounting plate 24, the mounting plate 24 is limited by the second sliding rail 23 during movement, shake generated by the mounting plate 24 during movement can be reduced, an upper end surface of the mounting plate 24 is fixedly connected with a connecting telescopic tube 15 having a reset function, a compression spring 17 is fixedly mounted inside the connecting telescopic tube 15, the compression spring 17 can play a reset role on the connecting telescopic tube 15, an upper end surface of the connecting telescopic tube 15 is fixedly connected with a connecting plate 14, an upper end surface of the connecting plate 14 is fixedly connected with a container fixing frame 16, a storage container 18 for storing water samples is clamped on an inner wall of the container fixing frame 16, a sliding plate 20 is slidably connected with a sliding plate 22 at a bottom of the fixing plate 20, specifically, the first sliding rail 21 is disposed at an outer surface of the first sliding rail 21 is slidably connected with the sliding plate 22, the second sliding plate 23 is consistent with the effect of the mounting plate 24, a connecting plate 15 is not repeated, a connecting telescopic tube 15 is fixedly connected with a connecting telescopic magnet 15, a connecting magnet 15 is fixedly connected with a magnetic door 25, a side of the two sides of the magnetic door is fixedly connected with a magnetic door 25, and a side is fixedly connected with a magnetic door 25, and is fixedly connected with a side to a side 25 to a magnetic door, and is fixedly connected with a side to a side 25.

Referring to fig. 2, 10, 11, a water outlet 34 is provided in the middle of the upper end of the first casing 3, a mounting ring 28 is rotatably connected to the upper end surface of the storage rope 2, a plurality of water inlets 30 are provided on the outer surface of the mounting ring 28, a connecting disc 33 is rotatably connected to the upper end of the mounting ring 28, a spiral fan 32 is fixedly connected to the upper end surface of the connecting disc 33, the spiral fan 32 is located right above the water outlet 34, a plurality of paddles 31 are fixedly connected to the outer surface of the connecting disc 33, when the first casing 3 enters the exploration well, when the first casing 3 is completely immersed in groundwater, the first casing 3 continues to be immersed downwards in the groundwater, the groundwater can collect samples through a sample mechanism 301 through the water inlets 30 provided on the mounting ring 28, after a group of sample mechanisms 301 collect samples, in order to prevent groundwater which is not equal to the exploration well from remaining in the water inlet cavity 29 in the process of moving down the first casing 3, therefore, when the first casing 3 is submerged, the paddle 31 is affected by resistance of water, when water flows through the paddle 31 on the connecting disc 33, the special shape of the paddle 31 changes the flow direction and speed of water, so that the momentum of water changes, according to the law of conservation of momentum in physics, the change of momentum generates equal and opposite force, the force is the force for pushing the paddle 31 to rotate with the connecting disc 33, at the moment, the connecting disc 33 drives the spiral fan 32 to rotate, and the spiral fan 32 sucks groundwater in the mounting ring 28 through the water outlet 34, so that the sample mechanism 301 can always take samples of groundwater with equal depth, and errors are reduced.

The working principle of the invention is as follows:

when the invention is used, the second shell 4 is prevented from being centered on the inner wall of the exploration well, the electric telescopic arm 10 is started at the moment, the electric telescopic arm 10 drives the contraction swing arm 12 to rotate, the outer surface of the contraction swing arm 12 is abutted against the stop post 35 to rotate, the contraction swing arm 12 is rotated to drive the anti-skid track 9 to be abutted against the inner wall of the exploration well, the crawler wheel is started, the crawler wheel drives the anti-skid track 9 to rotate on the inner wall of the exploration well, the anti-skid track 9 drives the second shell 4 to move downwards through the crawler wheel, the friction force on the inner wall of the exploration well can be increased, when the floating block 5 is contacted with underground water, the second shell 4 continues to move downwards at the moment due to the floating block 5 floating on the water surface under the action of the interaction force, the second shell 4 and the floating block 5 are abutted against the abutting spring 7 to contract, the triggering block 8 on the floating block 5 is abutted against the alarm 6, the alarm 6 is warned at the moment, workers are reminded that the floating block 5 is contacted with the water surface, the scale marks on the storage rope 2 are continuously aligned with the ground, and the length of the second shell 4 can be obtained by subtracting the length of the second shell 4 from the length of the storage rope 2;

when the first casing 3 is submerged in the exploration well, the depth of the first casing 3 is deeper, the water pressure received by the water blocks 26 is larger, the water blocks 26 are pushed under the action of underground water pressure, when the three groups of water blocks 26 move under the action of water pressure, as the distance between the first hole 19 and the outer surface of the first casing 3 is shortest, the water blocks 26 in the group of the first holes 19 reach and slide across the upper end surface of the first holes 19 first, at the moment, the underground water enters the first holes 19 through the water inlet cavities 29 and falls into the storage container 18 through the first holes 19, when the first casing 3 is submerged downwards, the underground water flows into the storage container 18 through the second holes 36 and the third holes 37 in sequence, the principle is the same as that of the first holes 19, and the sampling with different water level depths can be realized without redundant description;

when groundwater flows into the storage container 18, the storage container 18 extrudes the connecting telescopic pipe 15 as the water in the storage container 18 is more, the connecting telescopic pipe 15 is extruded and contracted, the connecting telescopic pipe 15 drives the connecting plate 14 to move downwards when contracted, the connecting plate 14 drives the rotating arm 13 to move downwards to drive the rotating arm 13 to pull the sliding plate 22 to move when moving downwards, the sliding plate 22 can seal the first hole 19 when moving, the first hole 19 is prevented from continuously conveying the groundwater into the storage container 18, and sampling and storage of the groundwater can be completed;

after the sampling is completed, the anti-skid crawler belt 9 is abutted to the inner wall of the exploration well, the crawler belt wheel is started to drive the anti-skid crawler belt 9 to move upwards, the crawler belt wheel drives the first casing 3 and the second casing 4 to move upwards, the electric telescopic arm 10 can be started to extend, the telescopic swing arm 12 can rotate along with the extension of the electric telescopic arm 10, at the moment, the anti-skid crawler belt 9 can be close to the inside of the second casing 4, the storage wheel 1 is driven to rotate through the rotating handle, the storage wheel 1 drives the storage rope 2 to store, the storage rope 2 can pull the first casing 3 to move upwards, after the first casing 3 is recovered, the magnetic door 25 is pulled by hand, the magnetic door 25 drives the mounting plate 24 to move to the outer surface of the first casing 3, and because the magnetic door 25 and the first casing 3 are installed in a magnetic attraction mode, waterproof adhesive tapes are installed at the abutted positions, the storage container 18 can be taken out from the container 16 without considering the problem of water leakage, and the groundwater can be sampled.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art, who is within the scope of the present invention, should make equivalent substitutions or modifications according to the technical scheme of the present invention and the inventive concept thereof, and should be covered by the scope of the present invention.

Claims

1. The utility model provides a hydrogeological exploration groundwater level device, includes first casing (3), its characterized in that, first casing (3) one side is provided with accomodates wheel (1), accomodate fixedly connected with between wheel (1) and first casing (3) accomodate rope (2), just accomodate rope (2) surface and be equipped with the scale mark that supplies the staff to detect accomodate rope (2) by the length that pulls out, three fixed plate (20) of first casing (3) inner wall fixedly connected with, first casing (3) bottom fixedly connected with second casing (4);

the utility model discloses a water surface warning device, including second casing (4), tilting mechanism (101) that steerable second casing (4) reciprocated is installed to inside fixed mounting of second casing (4), second casing (4) bottom fixed mounting has alarm (6) and butt spring (7), the bottom fixedly connected with kicking block (5) of butt spring (7), kicking block (5) up end fixedly connected with trigger piece (8), contact surface through buoyancy extrusion butt spring (7) and drive trigger piece (8) and alarm (6) butt when kicking block (5) contact surface, can trigger the alarm and remind the staff to contact the surface of water.

2. The hydrogeological groundwater level device according to claim 1, wherein the crawling mechanism (101) comprises an electric telescopic arm (10), four groups of anti-skid tracks (9) are arranged in the second casing (4), a plurality of crawler wheels are rotatably arranged on two sides of each anti-skid track (9), and the crawler wheels are connected with the electric telescopic arm (10) through a telescopic swing arm (12).

3. The hydrogeological exploration groundwater level device according to claim 2, wherein two ends of the shrinkage swing arm (12) are respectively connected with a crawler wheel and an electric telescopic arm (10) in a rotating mode, each two groups of symmetrical outer surfaces of the shrinkage swing arm (12) are abutted with a baffle column (35), an air telescopic pipe (11) is sleeved on the outer surface of the electric telescopic arm (10), and the air telescopic pipe (11) is fixedly connected with the shrinkage swing arm (12).

4. The hydrogeological prospecting groundwater level device according to claim 1, wherein three groups of sample mechanisms (301) capable of collecting samples for different water levels are fixedly mounted at the upper end of the fixing plate (20), the sample mechanisms (301) comprise a water inlet cavity (29), the water inlet cavity (29) is fixedly connected at the upper end of the fixing plate (20), and water blocks (26) are slidably connected inside the water inlet cavity (29).

5. The hydrogeological prospecting groundwater level device according to claim 4, wherein a hydraulic spring (27) is fixedly connected between the water pressure block (26) and the inner wall of the water inlet cavity (29), and the three groups of fixing plates (20) are provided with a first hole (19), a second hole (36) and a third hole (37).

6. The hydrogeological exploration groundwater level device according to claim 1, wherein three groups of storage mechanisms (201) capable of storing samples collected by the sample mechanism (301) are fixedly arranged at the bottom end of the fixing plate (20), the storage mechanisms (201) comprise mounting plates (24), the mounting plates (24) are slidably connected with the inner wall of the first casing (3), the upper end faces of the mounting plates (24) are fixedly connected with connecting telescopic pipes (15) with a reset function, and the upper end faces of the connecting telescopic pipes (15) are fixedly connected with connecting plates (14).

7. The hydrogeological exploration groundwater level device according to claim 6, wherein the upper end surface of the connecting plate (14) is fixedly connected with a container fixing frame (16), a storage container (18) for storing water samples is clamped on the inner wall of the container fixing frame (16), a sliding plate (22) is slidingly connected to the bottom of the fixing plate (20), a rotating arm (13) is rotatably connected between the sliding plate (22) and the connecting plate (14), and a magnetic door (25) is fixedly connected to one side, close to the outer surface of the first casing (3), of the mounting plate (24).

8. The hydrogeological groundwater level device according to claim 7, wherein strong magnets are fixedly installed on two sides of the magnetic door (25), and a waterproof rubber strip is fixedly connected to one side of the magnetic door (25) abutted to the first casing (3).

9. A method of using a hydrogeological groundwater level, for use in a hydrogeological groundwater level device according to any of the preceding claims 1-8, comprising the steps of:

s1: placing the second casing (4) in the middle of the inner wall of the exploration well, starting the electric telescopic arm (10) at the moment, driving the shrinkage swing arm (12) to rotate by the electric telescopic arm (10), enabling the outer surface of the shrinkage swing arm (12) to be in abutting joint with the baffle column (35), enabling the crawler wheel to drive the anti-skid crawler belt (9) to rotate on the inner wall of the exploration well when the shrinkage swing arm (12) rotates, enabling the crawler wheel to drive the anti-skid crawler belt (9) to move downwards through the crawler wheel, enabling the anti-skid crawler belt (9) to increase friction force on the inner wall of the exploration well, enabling the floating block (5) to float on the water surface under the action of the floating force when the floating block (5) contacts with groundwater, enabling the second casing (4) to move downwards continuously, enabling the second casing (4) to be in abutting joint with the floating block (5) to be in abutting joint with the spring (7) under the action of interaction force, enabling the triggering block (8) on the floating block (5) to be in abutting joint with the alarm (6), enabling the anti-skid crawler belt (9) to be in abutting joint with the alarm (6), enabling the length of the alarm rope (6) to be in the length of the water level to be measured, and the length of the alarm rope (2) to be level with the water level is measured, and the length of the floating rope (2) can be measured, and the length of the floating rope can be measured, and the length of the length can be measured is measured, and compared with the length of the length is measured;

s2: when the first casing (3) is submerged in the exploration well, the depth of the first casing (3) is deeper, the water pressure born by the water pressure blocks (26) is larger, the water pressure blocks (26) can be pushed under the action of underground water pressure, when the three groups of water pressure blocks (26) move under the action of the water pressure, as the distance from the first hole (19) to the outer surface of the first casing (3) is shortest, the water pressure blocks (26) of the group of the first hole (19) reach and slide over the upper end surface of the first hole (19) first, at the moment, underground water can enter the first hole (19) through the water inlet cavity (29), fall into the storage container (18) through the first hole (19), and when the first casing (3) is submerged downwards, the underground water flows into the inside the second hole (36) and then the third hole (37) in sequence, and the principle is the same as that of the first hole (19);

s3: when groundwater flows into the storage container (18), the storage container (18) is extruded to connect the telescopic pipe (15) because the more water in the storage container (18) is, the telescopic pipe (15) is extruded to shrink, the telescopic pipe (15) is connected to drive the connecting plate (14) to move downwards when shrinking, the connecting plate (14) can drive the rotating arm (13) to move downwards when moving downwards and the rotating arm (13) can pull the sliding plate (22) to move when moving downwards, the sliding plate (22) can seal the first hole (19) when moving, and the first hole (19) is prevented from continuously conveying the groundwater into the storage container (18).