CN219121351U

CN219121351U - Geological disaster deep displacement monitoring device

Info

Publication number: CN219121351U
Application number: CN202321044431.9U
Authority: CN
Inventors: 王建新; 张策; 丁立丰
Original assignee: National Institute of Natural Hazards
Current assignee: National Institute of Natural Hazards
Priority date: 2023-05-05
Filing date: 2023-05-05
Publication date: 2023-06-02
Anticipated expiration: 2033-05-05

Abstract

The utility model relates to the technical field of geological monitoring, in particular to a geological disaster deep displacement monitoring device which comprises a mounting plate and a plurality of inclinometer pipes pre-buried at observation points, wherein adjacent inclinometer pipes are connected through connecting pipes, a cover cylinder is arranged on the outer wall of the bottom of the mounting plate and is connected to the end part of the inclinometer pipes in a covering mode, a mounting frame is arranged on the outer wall of one side of the mounting plate, which is far away from the cover cylinder, a roller is rotationally arranged on the mounting frame, a driving piece is arranged on the outer wall of one side of the mounting frame, the driving end of the driving piece is connected with the roller, a cable is wound on the outer wall of the roller, and the cable penetrates through the mounting plate. In the process of detecting the inclinometer by sinking, the situation that the guide wheel is blocked at the connecting pipe is effectively avoided, the use is more convenient, and when the inclinometer bottoms out, the inclinometer can also play a role in protecting the inclinometer by a buffer mechanism to a certain extent, so that the use effect is better.

Description

Geological disaster deep displacement monitoring device

Technical Field

The utility model relates to the technical field of geological monitoring, in particular to a geological disaster deep displacement monitoring device.

Background

Geological disasters are geological phenomena such as debris flow, landslide, earthquake and the like which damage or destroy human lives and properties and the environment under natural or human factors, so that in order to reduce the loss caused by the geological disasters, a geological disaster deep displacement monitoring device is required to be used for real-time monitoring.

At present, the existing detection mode mainly detects through the mode of inclinometer, but the existing inclinometer still has certain shortcomings, in the use process, when the inclinometer passes through the connecting pipe between the inclinometers, the situation that the guide wheel outside the inclinometer is blocked in the connecting pipe easily occurs, the use effect is poor, and therefore, the design of a geological disaster deep displacement monitoring device is needed to solve the problems.

Disclosure of Invention

The utility model aims to solve the defects in the prior art, and provides a geological disaster deep displacement monitoring device.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

the utility model provides a geological disaster deep displacement monitoring devices, includes the mounting panel and pre-buried in a plurality of inclinations of observation point pipe, is connected through the takeover between the adjacent inclinations pipe, the bottom outer wall of mounting panel is provided with a cover section of thick bamboo, and the cover section of thick bamboo cover connects in the tip of inclinations pipe, one side outer wall that the cover section of thick bamboo was kept away from to the mounting panel is provided with the mounting bracket, and the mounting bracket rotation is provided with the roller, one side outer wall of mounting bracket is provided with the driving piece, and is connected between the drive end of driving piece and the roller, the outer wall wiring of roller has the cable, and the cable runs through the mounting panel, the tip of cable is provided with the inclinometer, set up the installation chamber in the inclinations appearance, and the inner wall of installation chamber is provided with the extensible member, and the extensible member's flexible end is provided with the ejector pad, the both sides inner wall of installation chamber has all been seted up the installing port, and the movable lever is provided with the guide pulley in the installing port, the tip of movable lever is provided with the elastic component one, one end and the guide pulley between the one end of elastic component is connected, and the other end of the inclinations piece and the inclinations appearance are connected with the chamfer, and the chamfer is located between the movable block and the chamfer is equipped with the chamfer and the movable connection of movable block, and the chamfer is still in the chamfer to one side of the movable connection:

the buffer mechanism is arranged at the end part of the inclinometer and is used for buffering when the inclinometer bottoms out;

the supporting mechanism is arranged on the outer wall of the mounting plate and used for adjusting the height of the mounting plate.

As still further aspects of the utility model: the buffer mechanism comprises a cavity formed in the inclinometer, a lifting block is movably arranged in the cavity, a movable rod penetrating through the end part of the inclinometer is arranged on the outer wall of the lifting block, a buffer seat is arranged at the end part of the movable rod, a slot is formed in the inner wall of the cavity, an inserting rod is inserted into the slot, the end part of the inserting rod is connected with the outer wall of the lifting block, an elastic piece II is sleeved on the outer side of the inserting rod, one end of the elastic piece II is connected with the outer wall of the lifting block, and the other end of the elastic piece II is connected with the inner wall of the cavity.

As still further aspects of the utility model: the inner wall of the buffer seat is provided with a rubber ring, and the inner wall of the rubber ring is matched with the end part of the inclinometer.

As still further aspects of the utility model: the inclinometer is characterized in that a fixed cavity is further formed in the inclinometer, the fixed cavity is communicated with the cavity through a connecting channel, the inner wall of the fixed cavity is connected with a movable plate through an elastic piece III, the outer wall of the movable plate is provided with a pressure sensor, and the outer wall of the lifting block is provided with a supporting rod for supporting the pressure sensor.

As still further aspects of the utility model: the driving piece and the telescopic piece are connected with a switch through wires, the switch is electrically connected with a controller, and the pressure sensor is electrically connected with the controller.

As still further aspects of the utility model: the supporting mechanism comprises supporting cylinders arranged at four corners of the outer wall of the mounting plate, screw rods are arranged in the supporting cylinders in a threaded mode, and supporting plates are arranged at the end portions of the screw rods.

As still further aspects of the utility model: the outer wall of mounting panel runs through fixedly to be provided with a fixed section of thick bamboo, and the cable runs through a fixed section of thick bamboo, the both ends of fixed section of thick bamboo all are provided with the wire and fight.

Compared with the prior art, the utility model has the beneficial effects that:

the utility model provides a geological disaster deep displacement monitoring device, when the deep displacement detection is needed to be carried out on an observation point, drilling is needed to be carried out on the observation point, the drilling depth exceeds the deepest displacement zone, then, the inclinometer pipes are sequentially put into the drilling, adjacent inclinometer pipes are connected by connecting pipes and are fixed by screws, backfilling can be carried out through raw soil and sand after the installation of the inclinometer pipes is confirmed to be intact, intermittent water injection is carried out during backfilling, the raw soil and sand are firmly combined with the hole wall after meeting water until the hole wall is reached, concrete is poured on the surface pipe orifice section of the inclinometer pipe, so as to protect the stability of the pipe orifice and the pipe orifice corner, when the inclinometer pipes of the observation point are needed to be detected to achieve the purpose of detecting the deep displacement, the cover cylinder is sleeved at the end part of the inclinometer pipe exposed out of the ground, the mounting plate is supported by a supporting mechanism, and then, the roller is driven to rotate by a driving piece, the cable is not broken, the inclinometer at the end part of the cable sinks into the inclinometer pipe, in the sinking process, the pushing block at the end part of the telescopic piece can prop against the movable block, the guide wheel at the end part of the movable rod is attached to the inner wall of the inclinometer pipe, the inclinometer pipe and the inclinometer pipe are ensured to be parallel, when the geological deep part is displaced, the inclinometer pipe can correspondingly perform inclination displacement, the inclination measured by the inclinometer is the inclination of the inclinometer pipe, the purpose of detecting the deep displacement can be achieved by detecting the inclinations of all the inclinometer pipes, and when the inclinometer pipe passes through a connecting pipe between the inclinometer pipes, the pushing block can be driven to move upwards through the telescopic piece, the limitation on the movable block is removed, the guide wheel can shrink inwards when passing through the connecting pipe, the elastic piece at the outer side of the movable rod is compressed, the condition that the guide wheel is blocked at the connecting pipe is effectively avoided, the use is more convenient, and when the inclinometer touches the bottom, the inclinometer can also play a certain role in buffering through the buffer mechanism, so that the inclinometer is protected, and the use effect is better.

Drawings

FIG. 1 is a schematic cross-sectional view of a geological disaster deep displacement monitoring device according to an embodiment of the present utility model;

FIG. 2 is an enlarged schematic view of the structure of FIG. 1 at A;

FIG. 3 is an enlarged schematic view of a buffer mechanism of a device for monitoring deep displacement of geological disasters according to an embodiment of the present utility model;

fig. 4 is an enlarged schematic view of an inclinometer of a geological disaster deep displacement monitoring device according to an embodiment of the present utility model.

In the figure: 1-inclinometer, 2-supporting mechanism, 3-mounting plate, 4-driving piece, 5-mounting frame, 6-roller, 7-wire bucket, 8-fixed cylinder, 9-supporting cylinder, 10-screw, 11-supporting plate, 12-cover cylinder, 13-cable, 14-inclinometer, 15-buffer mechanism, 16-mounting cavity, 17-expansion piece, 18-push block, 19-movable block, 20-movable rod, 21-guide wheel, 22-elastic piece one, 23-cavity, 24-lifting block, 25-supporting rod, 26-slot, 27-inserted rod, 28-elastic piece two, 29-fixed cavity, 30-elastic piece three, 31-movable plate, 32-pressure sensor, 33-connecting channel, 34-movable rod, 35-buffer seat, 36-rubber ring.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

As shown in fig. 1, 2 and 4, a geological disaster deep displacement monitoring device provided by an embodiment of the present utility model includes a mounting plate 3 and a plurality of inclinations 1 pre-buried at an observation point, wherein adjacent inclinations 1 are connected through connection pipes, a cover cylinder 12 is disposed on the bottom outer wall of the mounting plate 3, and the cover cylinder 12 is covered at the end of the inclinations 1, a mounting frame 5 is disposed on the outer wall of one side of the mounting plate 3 far away from the cover cylinder 12, a roller 6 is rotatably disposed in the mounting frame 5, a driving member 4 is disposed on the outer wall of one side of the mounting frame 5, the specific structure of the driving member 4 is not limited, in this embodiment, preferably, a servo motor is adopted for the driving member 4, the driving end of the driving member 4 is connected with the roller 6, a cable 13 is wound on the outer wall of the roller 6, the cable 13 penetrates through the mounting plate 3, an inclinometer 14 is disposed at the end of the cable 13, a mounting cavity 16 is disposed in the inclinometer 14, in this embodiment, preferably, the telescopic member 17 is an electric telescopic rod, the telescopic end of the telescopic member 17 is provided with a push block 18, both inner walls of both sides of the installation cavity 16 are provided with an installation opening, a movable rod 20 is movably arranged in the installation opening, the end of the movable rod 20 is provided with a guide wheel 21, the outer side of the movable rod 20 is sleeved with an elastic member I22, the specific structure of the elastic member I22 is not limited, in this embodiment, the elastic member I22 is preferably a spring, one end of the elastic member I22 is connected with the guide wheel 21, the other end of the elastic member I22 is connected with the outer wall of the inclinometer 14, the end of the movable rod 20 is provided with a movable block 19, the movable block 19 is positioned in the installation cavity 16, one side of the movable block 19 is provided with an inclined chamfer, and laminating mutually between chamfer and the ejector pad 18, still include:

the buffer mechanism 15 is arranged at the end part of the inclinometer 14 and is used for buffering when the inclinometer 14 touches the bottom;

the supporting mechanism 2, the supporting mechanism 2 sets up in the outer wall of mounting panel 3 for adjust the height of mounting panel 3.

When the deep displacement detection is needed for the observation point, drilling is needed at the observation point, the drilling depth exceeds the deepest displacement zone, then the inclinometer pipes 1 are sequentially put into the drilling holes one by one, the adjacent inclinometer pipes 1 are connected by connecting pipes and are fixed by screws, when the installation of the inclinometer pipes 1 is confirmed to be complete, backfilling can be carried out by raw soil and sand, intermittent water injection is carried out during backfilling, the raw soil and sand are firmly combined with the hole wall after meeting water until the hole opening, concrete is poured on the pipe opening section of the earth surface of the inclinometer pipes 1, so as to protect the stability of the pipe opening and the pipe opening corner, when the inclinometer pipes of the observation point are needed to be detected to achieve the aim of detecting the deep displacement, the cover cylinder 12 can be sleeved at the end part of the inclinometer pipes 1 exposed out of the ground, the mounting plate 3 is supported by the supporting mechanism 2, then the roller 6 can be driven to rotate by the driving piece 4, and the winding cable 13 is continuously released, the inclinometer 14 at the end part of the cable 13 is sunk into the inclinometer 1, in the sinking process, the push block 18 at the end part of the telescopic piece 17 can prop against the movable block 19, the guide wheel 21 at the end part of the movable rod 20 is attached to the inner wall of the inclinometer 1, so that the inclinometer 14 and the inclinometer 1 are ensured to be kept parallel, when the geological deep part is displaced, the inclinometer 1 can correspondingly perform inclination displacement, the inclination measured by the inclinometer 14 is the inclination of the inclinometer 1, the purpose of detecting the deep displacement can be achieved by detecting the inclination of all inclinometers 1, and when the inclinometer 14 passes through a connecting pipe between the inclinometers 1, the push block 18 can be driven to move upwards through the telescopic piece 17, the limitation on the movable block 19 is removed, the guide wheel 21 can shrink inwards when passing through the connecting pipe, the elastic piece 22 at the outer side of the movable rod 20 is compressed, the condition that the guide wheel 21 is blocked at the connecting pipe is effectively avoided, the use is more convenient, and when the inclinometer 14 touches the bottom, the buffer mechanism 15 can also play a certain role in buffering, so as to play a role in protecting the inclinometer 14, and the use effect is better.

As an embodiment of the present utility model, referring to fig. 3 and 4, the buffer mechanism 15 includes a cavity 23 opened in the inclinometer 14, a lifting block 24 is movably disposed in the cavity 23, a moving rod 34 penetrating through an end of the inclinometer 14 is disposed on an outer wall of the lifting block 24, a buffer seat 35 is disposed on an end of the moving rod 34, a slot 26 is opened on an inner wall of the cavity 23, an inserting rod 27 is inserted into the slot 26, an end of the inserting rod 27 is connected with an outer wall of the lifting block 24, an elastic member second 28 is sleeved on an outer side of the inserting rod 27, a specific structure of the elastic member second 28 is not limited, in this embodiment, preferably, one end of the elastic member second 28 is connected with an outer wall of the lifting block 24, and the other end of the elastic member second 28 is connected with an inner wall of the cavity 23, when the inclinometer 14 touches the bottom, the buffer seat 35 contacts with the bottom, and forces the lifting block 24 to move in the cavity 23, so that the inserting rod 27 is inserted into the slot 26, and the elastic member second 28 on an outer side of the inserting rod 27 is compressed, thereby achieving an effective buffer effect.

As an embodiment of the present utility model, referring to fig. 3, the inner wall of the buffer seat 35 is provided with the rubber ring 36, and the inner wall of the rubber ring 36 is matched with the end of the inclinometer 14, when the lifting block 24 moves up, the end of the inclinometer 14 can be wrapped by the buffer seat 35, so as to achieve a good protection effect, and the rubber ring 36 in the buffer seat 35 can further play a role in buffering, so that the protection effect is better.

As an embodiment of the present utility model, referring to fig. 3, a fixed cavity 29 is further provided in the inclinometer 14, and the fixed cavity 29 is communicated with the cavity 23 through a connection channel 33, an inner wall of the fixed cavity 29 is connected with a movable plate 31 through an elastic member three 30, a specific structure of the elastic member three 30 is not limited, in this embodiment, preferably, the elastic member three 30 adopts a spring, an outer wall of the movable plate 31 is provided with a pressure sensor 32, an outer wall of the lifting block 24 is provided with a supporting rod 25 for supporting the pressure sensor 32, when the lifting block 24 moves upwards, the supporting rod 25 can be promoted to enter the connection channel 33 and contact with the pressure sensor 32, when the pressure sensor 32 detects a pressure signal, the inclinometer 14 is enabled to touch the bottom, the rotation of the roller 6 can be stopped in time, and when the supporting rod 25 supports the pressure sensor 32, the movable plate 31 can also compress the elastic member three 30, so that the lifting block 24 still has a certain buffer space, and the use effect is better.

As an embodiment of the present utility model, the driving member 4 and the telescopic member 17 are both connected to a switch through a wire, and the switch is electrically connected to a controller, and the pressure sensor 32 is electrically connected to the controller.

As an embodiment of the present utility model, referring to fig. 1, the supporting mechanism 2 includes supporting cylinders 9 disposed at four corners of the outer wall of the mounting plate 3, screws 10 are screwed in the supporting cylinders 9, and supporting plates 11 are disposed at the ends of the screws 10, so that the height of the mounting plate 3 can be flexibly adjusted by rotating the screws 10 in the supporting cylinders 9, and the use effect is better.

As an embodiment of the present utility model, referring to fig. 1, the outer wall of the mounting plate 3 is fixedly provided with a fixing cylinder 8, and the cable 13 penetrates through the fixing cylinder 8, both ends of the fixing cylinder 8 are provided with a wire bucket 7, the guiding effect of the cable 13 can be achieved through the fixing cylinder 8, and abrasion between the inclined cable 13 and the end of the fixing cylinder 8 can be avoided under the effect of the wire bucket 7, so that the use effect is better.

When the device is used, when the deep displacement detection is needed to be carried out on the observation point, drilling is firstly needed to be carried out on the observation point, the drilling depth exceeds the deepest displacement zone, then the inclinometer pipes 1 are sequentially put into the drilling holes one by one, the adjacent inclinometer pipes 1 are connected by connecting pipes and are fixed by screws, when the installation of the inclinometer pipes 1 is confirmed to be perfect, the original earth and sand can be backfilled by the original earth and sand, water is intermittently injected during backfilling, the original earth and sand is firmly combined with the hole wall after meeting water until reaching the hole opening, concrete is poured on the pipe opening section of the earth surface of the inclinometer pipes 1, so as to protect the stability of the pipe opening and the pipe opening corner, when the inclinometer pipes of the observation point are needed to be detected to achieve the purpose of detecting the deep displacement, the cover cylinder 12 can be sleeved on the end part of the inclinometer pipes 1 exposed out of the ground, the mounting plate 3 is supported by the supporting mechanism 2, then the roller 6 can be driven by the driving piece 4 to rotate, and the winding cable 13 is continuously released, the inclinometer 14 at the end part of the cable 13 is sunk into the inclinometer 1, in the sinking process, the push block 18 at the end part of the telescopic piece 17 can prop against the movable block 19, so that the guide wheel 21 at the end part of the movable rod 20 is attached to the inner wall of the inclinometer 1, the inclinometer 14 and the inclinometer 1 are ensured to be parallel, when the geological deep part is displaced, the inclinometer 1 can correspondingly perform inclination displacement, the inclination measured by the inclinometer 14 is the inclination of the inclinometer 1, the purpose of detecting the deep displacement can be achieved by detecting the inclination of all inclinometers 1, and when the inclinometer 14 passes through a connecting pipe between the inclinometers 1, the push block 18 can be driven to move upwards through the telescopic piece 17, the limitation on the movable block 19 is removed, the guide wheel 21 can shrink inwards when passing through the connecting pipe, the elastic piece 22 at the outer side of the movable rod 20 is compressed, effectively avoid leading wheel 21 card stopper to appear in taking over the condition of department, it is more convenient to use, and can also play certain buffering through buffer gear 15 when inclinometer 14 touches the end, plays the guard action to inclinometer 14, and the result of use is better.

It should be specifically noted that, those skilled in the art should take the specification as a whole, and the technical solutions in the embodiments may also be combined appropriately to form other embodiments that can be understood by those skilled in the art, and the above embodiments only represent preferred embodiments of the present technical solution, which are described in more detail and are not to be construed as limiting the patent scope of the present technical solution.

Claims

1. The utility model provides a geological disaster deep displacement monitoring devices, includes the mounting panel and pre-buried in a plurality of inclinometers of observation point, is connected through the takeover between the adjacent inclinometers, its characterized in that, the bottom outer wall of mounting panel is provided with a cover section of thick bamboo, and the cover section of thick bamboo cover connects in the tip of inclinometers, one side outer wall that the cover section of thick bamboo was kept away from to the mounting panel is provided with the mounting bracket, and the mounting bracket rotation is provided with the roller, one side outer wall of mounting bracket is provided with the driving piece, and is connected between driving piece's drive end and the roller, the outer wall wiring of roller has the cable, and the cable runs through the mounting panel, the tip of cable is provided with the inclinometer, set up the installation chamber in the inclinometer, and the inner wall of installation chamber is provided with the extensible member, and the flexible end of extensible member is provided with the ejector pad, the both sides inner wall of installation chamber has all seted up the installation mouth, and the activity is provided with the movable lever in the installation mouth, the tip of movable lever is provided with the leading wheel, and the outside of movable lever cup joints elastic component one, be connected between one end and the leading wheel, and one end of elastic component and the inclined member are provided with the chamfer and chamfer, and the chamfer is located between the movable piece and the inclined joint of the movable piece, and the chamfer is located to one side of the movable piece.

2. The geological disaster deep displacement monitoring device according to claim 1, wherein the buffer mechanism comprises a cavity formed in the inclinometer, a lifting block is movably arranged in the cavity, a movable rod penetrating through the end of the inclinometer is arranged on the outer wall of the lifting block, a buffer seat is arranged at the end of the movable rod, a slot is formed in the inner wall of the cavity, an inserting rod is inserted into the slot, the end of the inserting rod is connected with the outer wall of the lifting block, an elastic piece II is sleeved on the outer side of the inserting rod, one end of the elastic piece II is connected with the outer wall of the lifting block, and the other end of the elastic piece II is connected with the inner wall of the cavity.

3. The geological disaster deep displacement monitoring device according to claim 2, wherein a rubber ring is arranged on the inner wall of the buffer seat, and the inner wall of the rubber ring is matched with the end part of the inclinometer.

4. The geological disaster deep displacement monitoring device according to claim 3, wherein a fixed cavity is further formed in the inclinometer, the fixed cavity is communicated with the cavity through a connecting channel, the inner wall of the fixed cavity is connected with a movable plate through an elastic piece III, the outer wall of the movable plate is provided with a pressure sensor, and the outer wall of the lifting block is provided with a supporting rod for supporting the pressure sensor.

5. The device for monitoring the displacement of a geological disaster in deep position according to claim 4, wherein the driving member and the telescopic member are connected with a switch through wires, the switch is electrically connected with a controller, and the pressure sensor is electrically connected with the controller.

6. The geological disaster deep displacement monitoring device according to claim 1, wherein the supporting mechanism comprises supporting cylinders arranged at four corners of the outer wall of the mounting plate, screws are arranged in the supporting cylinders in a threaded mode, and supporting plates are arranged at the ends of the screws.

7. The geological disaster deep displacement monitoring device according to claim 1, wherein a fixed cylinder is fixedly arranged on the outer wall of the mounting plate in a penetrating manner, cables penetrate through the fixed cylinder, and wire hoppers are arranged at two ends of the fixed cylinder.