CN220288571U - Geological disaster deep displacement monitoring device - Google Patents

Abstract

The utility model discloses a geological disaster deep displacement monitoring device which comprises a geological disaster deep displacement monitoring device body, wherein the geological disaster deep displacement monitoring device body comprises a mounting seat, a monitoring box and two inclined solar panels, wherein the monitoring box and the two inclined solar panels are fixedly arranged at the top of the mounting seat, and a U-shaped fixing seat is arranged below the mounting seat. The utility model is provided with a series of structures, is convenient for lifting and adjusting the monitoring box and the inclined solar panel, is convenient for subsequent lowering of height for personnel to directly maintain and overhaul the lower part, can buffer and unload force to the impact force of falling objects while protecting the upper part, reduces the hard resonance force downwards transmitted to the monitoring box, realizes the buffer and protection of falling objects of the monitoring box, improves the long-term protection stability, is convenient for automatically rotating and stirring the top of the semicircular transparent shield to remove slag when impacted by the falling objects, prevents the accumulation of impurities from influencing the subsequent buffer and protection work, and improves the protection effect.

Description

Geological disaster deep displacement monitoring device

Technical Field

The utility model relates to the technical field of displacement monitoring equipment, 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.

Through retrieving, current patent number CN215572805U discloses a geological disaster deep displacement monitoring devices, the on-line screen storage device comprises a base, fixed mounting has the support column on the base, first slide has been seted up on the support column, sliding connection is provided with the mount pad on the first slide, there is the monitoring case through fixed establishment fixed mounting on the mount pad, mount pad both sides fixed mounting has the bracing piece, fixed mounting has the mounting panel on the support column, install solar panel on the mounting panel articulatedly, the support column is kept away from first slide side and has been seted up the second slide, be provided with the actuating mechanism that is used for driving the vertical motion of mount pad on the mount pad, this geological disaster deep displacement monitoring devices is favorable to realizing the fixed to monitoring case and solar panel, improves stability, realizes simultaneously that the stability to monitoring case and solar panel rises and descends, makes things convenient for operating personnel to install and observe, and the practicality is strong.

The geological disaster deep displacement monitoring device disclosed in the patent can lift the monitoring box and the solar panel, is convenient for operators to observe and subsequently lower the height for overhauling and maintenance, but still has some defects:

because the monitoring installation position is an outdoor zone which is easy to generate landslide and earthquake, the environment is severe, the phenomenon of falling objects is difficult to avoid in weather and wind, and because the technology is not provided with a structure for preventing and protecting the monitoring box and the solar panel from falling objects, the monitoring box is directly positioned at the upper part, and the risk of being impacted and damaged by the falling objects is high; in addition, although the shield is mounted on the upper part in the prior art for shielding, the hard resonance force transmitted downwards is large when the shield is impacted by falling objects, the falling objects are easy to adhere and accumulate on the upper part, the weight of the upper part is easy to be gradually increased and crushed, and the protection effect is not ideal.

Disclosure of Invention

The utility model aims to provide a geological disaster deep displacement monitoring device for solving the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the geological disaster deep displacement monitoring device comprises a geological disaster deep displacement monitoring device body, wherein the geological disaster deep displacement monitoring device body comprises a mounting seat, a monitoring box fixedly mounted at the top of the mounting seat and two inclined solar panels, a U-shaped fixing seat is arranged below the mounting seat, a lifting support component is mounted between the bottom of the mounting seat and the U-shaped fixing seat and used for lifting and adjusting the mounting seat, and the effects of conveniently lifting and adjusting the monitoring box and maintaining the subsequent lowering height in geological disaster deep displacement monitoring work are achieved;

the top of the mounting seat is fixedly connected with a self-cleaning buffer protection mechanism; the self-cleaning buffer protection mechanism comprises a rectangular box fixedly connected to the top of the mounting seat, the bottom of the rectangular box is provided with an opening, a semicircular transparent shield is arranged above the rectangular box and positioned above the inclined solar panel and the monitoring box, a U-shaped seat is fixedly connected to the bottom of the semicircular transparent shield, a vertical elastic supporting component is fixedly connected to the bottom of the U-shaped seat, the bottom of the vertical elastic supporting component slidingly extends into the rectangular box, a pressure sensor is fixedly embedded at the top of the mounting seat, the top of the pressure sensor is fixedly connected with the bottom of the vertical elastic supporting component, the semicircular transparent shield is used for realizing the protection of the monitoring box and the inclined solar panel from falling objects at the upper part, and the vertical elastic supporting component is used for buffering unloading force and extruding the pressure sensor when the semicircular transparent shield is impacted by falling objects;

the automatic slag removing device is characterized in that a telescopic rotary driving assembly is rotationally connected to the inner wall of the bottom of the U-shaped seat, an arc-shaped slag removing rod is fixedly connected to the top end of the telescopic rotary driving assembly, the bottom of the arc-shaped slag removing rod is movably contacted with the right side of the top of the semicircular transparent shield, a driving motor is fixedly mounted on the inner wall of the top of the rectangular box, an output shaft is fixedly connected with the telescopic rotary driving assembly, a PLC (programmable logic controller) is fixedly mounted on the inner wall of the top of the rectangular box, a pressure sensor and the driving motor are electrically connected with the PLC, the pressure sensor is used for detecting extrusion force and transmitting the extrusion force to the PLC, the PLC is used for controlling the driving motor to automatically open when exceeding a preset value, and the telescopic rotary driving assembly is used for controlling the arc-shaped slag removing rod to stir slag to the top of the semicircular transparent shield when the driving motor is started.

Preferably, the lifting support assembly comprises a rectangular pipe fixedly connected to the top of the U-shaped fixing seat, a rectangular supporting rod is sleeved in the rectangular pipe in a sliding manner, the top end of the rectangular supporting rod is fixedly connected with the bottom of the mounting seat, a screw is rotatably mounted on the top of the U-shaped fixing seat, a rectangular supporting rod is sleeved on the screw in a threaded manner, and the bottom end of the screw extends into the U-shaped fixing seat and is fixedly connected with a knob; the rectangular pipe, the rectangular supporting rod, the screw rod and the knob are matched, when the knob is rotated to drive the screw rod to rotate, the screw rod is utilized to rotate to drive the rectangular supporting rod to move up and down, and lifting adjustment of the mounting seat is achieved, so that lifting adjustment and subsequent lowering of the monitoring box are convenient to maintain in geological disaster deep position monitoring work.

Preferably, the vertical elastic support assembly comprises four vertical guide rods which are rectangular and fixedly connected to the bottom of the U-shaped seat, the bottom ends of the four vertical guide rods extend into a rectangular box and are fixedly connected with the same lifting plate, the rectangular box is slidably sleeved on the four vertical guide rods, the bottom of the lifting plate is fixedly connected with two buffer springs, and the bottom ends of the buffer springs are fixedly connected with the top of the pressure sensor; the vertical guide rods, the lifting plates and the buffer springs are matched, when the semicircular transparent shield is impacted by falling objects to move downwards, the U-shaped seat is driven to move downwards, the U-shaped seat drives the lifting plates to move downwards through the four vertical guide rods, the lifting plates compress the buffer springs downwards, the buffer springs are utilized to buffer and unload impact force, and the pressure sensor is utilized to detect extrusion force when impacted and transmit the extrusion force to the PLC controller.

Preferably, the telescopic rotary driving assembly comprises a rotating shaft which is rotationally connected to the inner wall of the bottom of the U-shaped seat, the top end of the rotating shaft is fixedly connected with the left side of the bottom of the arc-shaped slag stirring rod, a square hole is formed in the bottom end of the rotating shaft, fang Zhuaigan is sleeved in the square hole in a sliding manner, and the bottom end of the square rotating rod is fixedly connected with the top end of an output shaft of the driving motor; the pivot, square hole and Fang Zhuaigan cooperation that set up can drive the square hole through the pivot and slide from top to bottom at square bull stick when semicircle transparent guard shield moves down, and the pressure value that the PLC controller received surpasses the control driving motor automatic start, and driving motor drive square bull stick rotates, and square bull stick utilizes its edges and corners card in square hole to drive the pivot and rotates, and the pivot drives the arc and dials the sediment pole and rotate and stir the scarfing cinder to semicircle transparent guard shield top, realizes the automatic effect of stirring the clear thing that falls that will drop, and buffer spring resets, and when pressure was less than the default, PLC controller control driving motor automatic shutdown.

Preferably, the bottom of the rectangular supporting rod is provided with a thread groove in threaded connection with the screw rod.

Preferably, a round through hole is formed in the center of the top of the semicircular transparent shield, and the rotating shaft is positioned in the round through hole and is not in contact with the inner wall of the round through hole.

Preferably, the bottom right side fixedly connected with battery of mount pad, fixed and electric connection have same solar controller between two oblique solar panels, solar controller and monitoring box all with battery electric connection, driving motor and PLC controller all with battery electric connection.

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

1. according to the geological disaster deep displacement monitoring device, the lifting support assembly is matched with the mounting seat, so that the mounting seat can be lifted and adjusted, the lifting and adjustment of the monitoring box and the inclined solar panel are realized, and the subsequent lowering of the height is facilitated for personnel to directly maintain and overhaul the lower part;

2. according to the geological disaster deep displacement monitoring device, the semicircular transparent shield, the U-shaped seat and the vertical elastic support component are matched, so that falling objects can be prevented from being blocked and protected on the upper part of the monitoring box and the inclined solar panel, impact force can be buffered and unloaded when the falling objects are impacted, the rigid resonance force downwards transmitted to the monitoring box is reduced, the falling objects can be prevented from being buffered and blocked and protected on the monitoring box, and the long-term protection stability is improved;

3. the utility model provides a geological disaster deep displacement monitoring devices, through vertical elastic support subassembly that sets up, a pressure sensor, the PLC controller, driving motor, arc dials sediment pole and flexible rotary driving subassembly, after utilizing the PLC controller to predetermine the pressure value that control driving motor was opened and close, can detect the extrusion force when receiving dropping the thing impact, and automatic control driving motor opens when the extrusion force surpasss the default, realize that the arc dials sediment pole and rotates and stir the scarfing cinder at the top of semicircle transparent guard shield, prevent that impurity from piling up and influencing follow-up buffering fender and protect work.

The utility model is provided with a series of structures, is convenient for lifting and adjusting the monitoring box and the inclined solar panel, is convenient for subsequent lowering of height for personnel to directly maintain and overhaul the lower part, can buffer and unload force to the impact force of falling objects while protecting the upper part, reduces the hard resonance force downwards transmitted to the monitoring box, realizes the buffer and protection of falling objects of the monitoring box, improves the long-term protection stability, is convenient for automatically rotating and stirring the top of the semicircular transparent shield to remove slag when impacted by the falling objects, prevents the accumulation of impurities from influencing the subsequent buffer and protection work, and improves the protection effect.

Drawings

FIG. 1 is a schematic overall perspective view of the present utility model;

FIG. 2 is a schematic view of a front cross-sectional structure of the present utility model;

fig. 3 is an enlarged schematic view of the portion a in fig. 2 according to the present utility model.

In the figure: 1. a mounting base; 100. a monitoring box; 101. an oblique solar panel; 2. a rectangular strut; 3. a rectangular tube; 4. a screw; 5. a semicircular transparent shield; 6. a rectangular box; 7. a U-shaped seat; 8. a vertical guide rod; 9. a lifting plate; 10. a buffer spring; 11. a pressure sensor; 12. a PLC controller; 13. a driving motor; 14. a square rotating rod; 15. a rotating shaft; 16. arc slag pulling rod.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

As shown in fig. 1 to 3, the geological disaster deep displacement monitoring device provided by the embodiment comprises a geological disaster deep displacement monitoring device body, wherein the geological disaster deep displacement monitoring device body comprises a mounting seat 1, a monitoring box 100 and two inclined solar panels 101 which are fixedly arranged at the top of the mounting seat 1, a storage battery is fixedly connected to the right side of the bottom of the mounting seat 1, the two inclined solar panels 101 are fixedly and electrically connected with the same solar controller, the solar controller and the monitoring box 100 are electrically connected with the storage battery, a U-shaped fixing seat is arranged below the mounting seat 1, bolt mounting holes are formed in four corners at the top of the U-shaped fixing seat and are used for mounting and fixing the U-shaped fixing seat at a geological disaster position to be monitored by personnel through external bolts or anchor rods, and a lifting support component is arranged between the bottom of the mounting seat 1 and the U-shaped fixing seat and is used for lifting and adjusting the mounting seat 1, so that the lifting and adjusting of the monitoring box 100 and the subsequent lowering height of the monitoring box 100 in the geological disaster deep displacement monitoring work are convenient to maintain;

the top of the mounting seat 1 is fixedly connected with a self-cleaning buffer protection mechanism; the self-cleaning buffer protection mechanism comprises a rectangular box 6 fixedly connected to the top of a mounting seat 1, the bottom of the rectangular box 6 is provided with an opening, a semicircular transparent shield 5 is arranged above the rectangular box 6, the semicircular transparent shield 5 is positioned above an inclined solar panel 101 and a monitoring box 100, a U-shaped seat 7 is fixedly connected to the bottom of the semicircular transparent shield 5, a vertical elastic support component is fixedly connected to the bottom of the U-shaped seat 7, the bottom of the vertical elastic support component is slidingly extended into the rectangular box 6, a pressure sensor 11 with the top being a detection end is fixedly embedded in the top of the mounting seat 1, an embedded groove with the front side being the opening is formed in the top of the mounting seat 1, the bottom inner wall of the embedded groove is fixedly connected with the bottom of the pressure sensor 11, the pressure sensor 11 is embedded and fixed at the top of the mounting seat 1 through the embedded groove, the top of the pressure sensor 11 is fixedly connected with the bottom end of the vertical elastic support component, the upper part is used for preventing falling objects of the monitoring box 100 and the inclined solar panel 101 from being protected, and the vertical elastic support component is used for buffering and unloading force when the semicircular transparent shield 5 is impacted by falling objects and extruding the pressure sensor 11; the bottom inner wall of the U-shaped seat 7 is rotationally connected with a telescopic rotary driving assembly, the top end of the telescopic rotary driving assembly is fixedly connected with an arc slag stirring rod 16, the bottom of the arc slag stirring rod 16 is movably contacted with the right side of the top of the semicircular transparent shield 5, a driving motor 13 with an output shaft fixedly connected with the telescopic rotary driving assembly is fixedly installed on the top inner wall of the rectangular box 6, a PLC (programmable logic controller) 12 is fixedly installed on the top inner wall of the rectangular box 6, a pressure sensor 11 and the driving motor 13 are electrically connected with the PLC 12, the driving motor 13 and the PLC 12 are electrically connected with a storage battery, the extrusion force is detected by the pressure sensor 11 and transmitted to the PLC 12, the driving motor 13 is controlled to be automatically started when the preset value is exceeded by the PLC 12, and the telescopic rotary driving assembly is used for controlling the arc slag stirring rod 16 to stir the slag cleaning on the top of the semicircular transparent shield 5 when the driving motor 13 is started.

Specifically, the lifting support assembly comprises a rectangular pipe 3 fixedly connected to the top of the U-shaped fixing seat, a rectangular supporting rod 2 is sleeved in the rectangular pipe 3 in a sliding manner, a limit groove is formed in the right side of the rectangular supporting rod 2, a limit block which is in sliding connection with the limit groove is fixedly connected to the inner wall of the right side of the rectangular pipe 3, the effect of limiting and preventing the rectangular supporting rod 2 from falling off is achieved, the top end of the rectangular supporting rod 2 is fixedly connected with the bottom of the mounting seat 1, a screw 4 is rotatably mounted on the top of the U-shaped fixing seat, a rotating hole is formed in the top of the U-shaped fixing seat, a first bearing is fixedly sleeved in the rotating hole, the inner side of an inner ring of the first bearing is fixedly connected with the outer side of the screw 4, the screw 4 is rotatably connected with the top of the U-shaped fixing seat through the first bearing, the effect of rotatably mounting the screw 4 is achieved, the rectangular supporting rod 2 is sleeved on the screw 4 through threads, a thread groove which is in threaded connection with the screw 4 is formed in the bottom end of the rectangular supporting rod 2, the screw 4 is conveniently driven to move up and down when the screw 4 rotates, and the screw 4 is fixedly connected with a knob; rectangular pipe 3, rectangular branch 2, screw rod 4 and the knob cooperation that set up, when rotating the knob and driving screw rod 4 rotation, utilize screw rod 4 rotation to drive rectangular branch 2 and reciprocate, realize the adjustment of going up and down to mount pad 1 to this is convenient to maintain monitoring box 100 lift adjustment and follow-up reduction height in the monitoring of geological disaster deep displacement work.

Further, the vertical elastic support assembly comprises four vertical guide rods 8 which are fixedly connected to the bottom of the U-shaped seat 7 in a rectangular shape, the bottom ends of the four vertical guide rods 8 extend into the rectangular box 6 and are fixedly connected with the same lifting plate 9, the rectangular box 6 is slidably sleeved on the four vertical guide rods 8, four vertical guide holes which are respectively in sliding contact with the outer sides of the corresponding vertical guide rods 8 are formed in the inner wall of the top of the rectangular box 6, the rectangular box 6 is slidably sleeved on the four vertical guide rods 8 through the four vertical guide holes, the effect of vertically sliding and guiding the vertical guide rods 8 is achieved, the bottom of the lifting plate 9 is fixedly connected with two buffer springs 10, the bottom ends of the buffer springs 10 are fixedly connected with the top of the pressure sensor 11, and a stop block matched with the lifting plate 9 is also fixedly arranged on the inner wall of the right side of the rectangular box 6; the vertical guide rods 8, the lifting plates 9 and the buffer springs 10 are arranged in a matched mode, when the semicircular transparent shield 5 is impacted by falling objects to move downwards, the U-shaped seat 7 is driven to move downwards, the U-shaped seat 7 drives the lifting plates 9 to move downwards through the four vertical guide rods 8, the lifting plates 9 compress the buffer springs 10 downwards, impact force buffering and unloading are achieved through the elasticity of the buffer springs 10, and the extrusion force generated when the semicircular transparent shield 5 is impacted is detected through the pressure sensor 11 and is transmitted to the PLC 12.

Further, the telescopic rotary driving assembly comprises a rotary shaft 15 rotatably connected to the inner wall of the bottom of the U-shaped seat 7, wherein a circular through hole is formed in the inner wall of the bottom of the U-shaped seat 7, a second bearing is fixedly sleeved in the circular through hole, an inner ring of the second bearing is fixedly sleeved on the outer side of the rotary shaft 15, the rotary shaft 15 is rotatably connected with the inner wall of the bottom of the U-shaped seat 7 through the second bearing, the rotary shaft 15 is rotatably mounted on the rotary shaft 15, the top end of the rotary shaft 15 is fixedly connected with the left side of the bottom of the arc-shaped slag stirring rod 16, a circular through hole is formed in the center of the top of the semicircular transparent shield 5, the rotary shaft 15 is positioned in the circular through hole and is not in contact with the inner wall of the circular through hole, the rotary shaft 15 passes through the circular through hole, a square rotary rod 14 is arranged at the bottom end of the rotary shaft 15, and a square rotary rod 14 is fixedly connected with the top end of an output shaft of the driving motor 13 in the square hole in a sliding mode; the rotating shaft 15, square hole and square rotating rod 14 that set up cooperate, can drive square hole and slide from top to bottom at square rotating rod 14 through rotating shaft 15 when semicircle transparent guard 5 moves down, the pressure value that PLC controller 12 received surpasses the control driving motor 13 automatic start, driving motor 13 drives square rotating rod 14 rotation, square rotating rod 14 utilizes its self edges and corners card in square hole to drive rotating shaft 15 rotation, rotating shaft 15 drives arc and dials sediment pole 16 rotation and stir the scarfing cinder at semicircle transparent guard 5 top, realize the effect of automatic stirring the thing that drops and clearly fall, prevent impurity accumulation influence follow-up buffering fender effect, along with the impurity is clearly fallen, buffer spring 10 resets, the extrusion force reduces, when being less than the default, PLC controller 12 controls driving motor 13 self-closing.

The application method of the embodiment is as follows: when the monitoring box 100 needs to be adjusted in a lifting manner, the knob is rotated to drive the screw 4 to rotate, the rectangular support rod 2 is driven to slide up and down in the rectangular pipe 3 by the rotation of the screw 4, the rectangular pipe 3 drives the mounting seat 1 to move up and down, the lifting adjustment of the monitoring box 100 and the inclined solar panel 101 is realized, and the subsequent lowering of the height is facilitated by utilizing the lifting adjustment manner, so that the personnel can directly maintain and overhaul the lower part;

the semicircular transparent shield 5 is utilized to shield the monitoring box 100 and the inclined solar panel 101 from the upper side, the falling object blocking and protecting effect is realized, the PLC 12 is utilized to preset a pressure value for controlling the opening and closing of the driving motor 13, when the falling object is impacted by accident, the semicircular transparent shield 5 positioned above is impacted to move downwards and drive the U-shaped seat 7 to displace downwards, the U-shaped seat 7 drives the rotating shaft 15 to slide downwards on the square rotating rod 14, meanwhile, the U-shaped seat 7 drives the lifting plate 9 to displace downwards through the four vertical guide rods 8 and compresses the buffer spring 10, the impact force buffering and unloading force is realized by utilizing the elasticity of the buffer spring 10, the risk of the semicircular transparent shield 5 being damaged by impact is reduced, the impact force energy can be attenuated, the hard resonance force downwards transmitted to the monitoring box 100 is reduced, the buffering and protecting effect is realized, and the long-term protection stability is improved;

when the buffer spring 10 is compressed, the downward extrusion force of the buffer spring 10 to the pressure sensor 11 is increased, the extrusion force is detected by the pressure sensor 11 and transmitted to the PLC 12, when the pressure value exceeds a preset value, the PLC 12 controls the driving motor 13 to automatically start, the driving motor 13 drives the square rotating rod 14 to rotate, the square rotating rod 14 is clamped with the edge angle of the square hole by utilizing the edge angle to drive the rotating shaft 15 to rotate, the rotating shaft 15 drives the arc-shaped slag stirring rod 16 to rotate to stir slag removal on the top of the semicircular transparent shield 5, the effect of stirring and cleaning falling objects is achieved automatically, the effect of preventing the impurity accumulation from affecting the subsequent buffer blocking effect is achieved, the upper weight is reduced along with the falling of the impurities, the buffer spring 10 is reset, the extrusion force is reduced, and when the pressure value received by the PLC 12 is lower than the preset value, the driving motor 13 is controlled to be automatically closed, and buffer blocking work is performed again;

the PLC controller 12, the driving motor 13 and the pressure sensor 11 in the present utility model are well known to those skilled in the art, and all belong to conventional means or common knowledge, so that those skilled in the art can perform any optional matching according to their needs or convenience, in addition, the PLC controller 12 receives the pressure value transmitted by the pressure sensor 11 and controls the driving motor 13 to be turned on when the pressure value is higher than the preset value, and all belong to conventional means or common knowledge for setting control modes of controller parameters well known to those skilled in the art, so that no further description is given here.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present utility model has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (7)

1. The utility model provides a geological disaster deep displacement monitoring devices, includes geological disaster deep displacement monitoring devices body, geological disaster deep displacement monitoring devices body includes mount pad (1) and fixed mounting at monitoring box (100) and two oblique solar panel (101) at mount pad (1) top, its characterized in that: a U-shaped fixing seat is arranged below the mounting seat (1), a lifting support assembly is arranged between the bottom of the mounting seat (1) and the U-shaped fixing seat, and the top of the mounting seat (1) is fixedly connected with a self-cleaning buffer protection mechanism;

the self-cleaning buffer protection mechanism comprises a rectangular box (6) fixedly connected to the top of a mounting seat (1), the bottom of the rectangular box (6) is provided with an opening, a semicircular transparent shield (5) is arranged above the rectangular box (6), the semicircular transparent shield (5) is positioned above an inclined solar panel (101) and a monitoring box (100), the bottom of the semicircular transparent shield (5) is fixedly connected with a U-shaped seat (7), the bottom of the U-shaped seat (7) is fixedly connected with a vertical elastic supporting component, the bottom of the vertical elastic supporting component slidingly extends into the rectangular box (6), the top of the mounting seat (1) is embedded and fixed with a pressure sensor (11), and the top of the pressure sensor (11) is fixedly connected with the bottom of the vertical elastic supporting component; the automatic slag stirring device is characterized in that a telescopic rotary driving assembly is rotationally connected to the inner wall of the bottom of the U-shaped seat (7), an arc slag stirring rod (16) is fixedly connected to the top end of the telescopic rotary driving assembly, the bottom of the arc slag stirring rod (16) is movably contacted with the right side of the top of the semicircular transparent shield (5), a driving motor (13) fixedly connected with an output shaft and the telescopic rotary driving assembly is fixedly mounted on the inner wall of the top of the rectangular box (6), a PLC (programmable logic controller) is fixedly mounted on the inner wall of the top of the rectangular box (6), and a pressure sensor (11) and the driving motor (13) are electrically connected with the PLC (12).

2. The geological disaster deep displacement monitoring device as claimed in claim 1, wherein: the lifting support assembly comprises a rectangular pipe (3) fixedly connected to the top of the U-shaped fixing seat, a rectangular supporting rod (2) is sleeved in the rectangular pipe (3) in a sliding mode, the top end of the rectangular supporting rod (2) is fixedly connected with the bottom of the mounting seat (1), a screw rod (4) is rotatably mounted at the top of the U-shaped fixing seat, the rectangular supporting rod (2) is sleeved on the screw rod (4) in a threaded mode, and the bottom end of the screw rod (4) extends into the U-shaped fixing seat and is fixedly connected with a knob.

3. A geological disaster deep displacement monitoring device as claimed in claim 2, wherein: the vertical elastic support assembly comprises four vertical guide rods (8) which are fixedly connected to the bottom of a U-shaped seat (7), wherein the bottom ends of the four vertical guide rods (8) are all extended into a rectangular box (6) and fixedly connected with one lifting plate (9), the rectangular box (6) is slidably sleeved on the four vertical guide rods (8), two buffer springs (10) are fixedly connected to the bottom of the lifting plate (9), and the bottom ends of the buffer springs (10) are fixedly connected with the top of a pressure sensor (11).

4. A geological disaster deep displacement monitoring device according to claim 3, wherein: the telescopic rotary driving assembly comprises a rotating shaft (15) which is rotationally connected to the inner wall of the bottom of the U-shaped seat (7), the top end of the rotating shaft (15) is fixedly connected with the left side of the bottom of the arc slag stirring rod (16), a square hole is formed in the bottom end of the rotating shaft (15), a Fang Zhuaigan (14) is sleeved in the square hole in a sliding mode, and the bottom end of the square rotating rod (14) is fixedly connected with the top end of an output shaft of the driving motor (13).

5. A geological disaster deep displacement monitoring device as claimed in claim 2, wherein: the bottom of the rectangular supporting rod (2) is provided with a thread groove in threaded connection with the screw rod (4).

6. The geological disaster deep displacement monitoring device as claimed in claim 4, wherein: the center of the top of the semicircular transparent shield (5) is provided with a circular through hole, and the rotating shaft (15) is positioned in the circular through hole and is not contacted with the inner wall of the circular through hole.

7. The geological disaster deep displacement monitoring device as claimed in claim 1, wherein: the solar energy monitoring device is characterized in that a storage battery is fixedly connected to the right side of the bottom of the mounting seat (1), the two inclined solar panels (101) are fixedly and electrically connected with the same solar energy controller, the solar energy controller and the monitoring box (100) are electrically connected with the storage battery, and the driving motor (13) and the PLC (12) are electrically connected with the storage battery.