CN116798192B

CN116798192B - Geological disaster monitoring equipment

Info

Publication number: CN116798192B
Application number: CN202311047190.8A
Authority: CN
Inventors: 洪培隆; 杨思强; 张佳荣
Original assignee: Fuzhou Stack Technology Co ltd
Current assignee: Fuzhou Stack Technology Co ltd
Priority date: 2023-08-21
Filing date: 2023-08-21
Publication date: 2023-11-21
Anticipated expiration: 2043-08-21
Also published as: CN116798192A

Abstract

The invention discloses geological disaster monitoring equipment, and belongs to the technical field of geological disaster monitoring. The utility model provides a geological disaster monitoring facilities, includes the monitoring support frame, rotation image shooting ware is installed to the upper end of monitoring support frame, just the one end of monitoring support frame is provided with the mount, the one end of mount is provided with rainfall monitoring component, the lower extreme of rainfall monitoring component is provided with the siren, the one end of siren is provided with the light, coincides with the hole that leaks through the kicking block, rotation image shooting ware can carry out image shooting operation this moment, and the image of shooting can carry relevant department through the control box, like this the staff can be according to the position of the interior reference thing of image change, whether decide to trigger the alarm, thereby can let the staff real-time data content in the observation image, and then improved the timeliness of information to a certain extent, and the accuracy, still reduced the time that the information difference was spaced to a certain extent.

Description

Geological disaster monitoring equipment

Technical Field

The invention relates to the technical field of geological disaster monitoring, in particular to geological disaster monitoring equipment.

Background

At present, geological disasters are formed under natural or human factors, loss of life and property of human beings and geological phenomena of damage to the environment are caused, common geological disasters such as collapse, landslide, mud-rock flow and the like are formed, in order to timely grasp occurrence trend of the geological disasters, personnel and property loss are reduced, geological disaster monitoring equipment is arranged essentially, and land water seepage rates of all areas are different, so that precipitation monitored in all areas are different, but most of the geological disaster monitoring equipment at present only can send precipitation information to relevant departments when monitoring precipitation reaches monitoring standards, so that information difference occurs, because the relevant departments need to send staff to the areas for monitoring after receiving the information, the monitored data do not accord with the received information, early warning cannot be performed timely before the geological disasters occur, and further economic losses caused by the geological disasters are enlarged.

Disclosure of Invention

The utility model provides a geological disaster monitoring facilities, includes the monitoring support frame, rotation image shooting ware is installed to the upper end of monitoring support frame, just the one end of monitoring support frame is provided with the mount, the one end of mount is provided with rainfall monitoring module, the lower extreme of rainfall monitoring module is provided with the siren, the one end of siren is provided with the light, just the lower extreme of monitoring support frame is provided with the base, the upper end of base is provided with fixed subassembly, fixed subassembly's upper end is provided with the movable assembly;

the rain monitoring assembly comprises a collecting cavity, a conical connecting block, a water leakage hole, a cylindrical water leakage block, a floating block, a water leakage groove and a drainage assembly, wherein the conical connecting block is arranged at the upper end of the collecting cavity, the water leakage hole is formed in the lower end of the conical connecting block, the cylindrical water leakage block is arranged in the collecting cavity, the floating block is arranged in the cylindrical water leakage block, the water leakage groove is arranged on the outer side surface of the cylindrical water leakage block, the guiding function is achieved by the water leakage groove, meanwhile, the water leakage groove is sealed when the floating block is positioned at the bottom of the water leakage groove, rainwater collected in the collecting cavity is conveyed into the drainage assembly through the water leakage groove when the floating block moves upwards, the floating block is matched with the water leakage hole when the floating block moves to the top end of the water leakage groove, the sealing collecting cavity is achieved, and the drainage assembly is arranged at the lower end of the floating block;

the drainage assembly comprises a drainage pipe, a water containing pipe, a water outlet hole, a reset spring and an atomization drainage hole, wherein the water containing pipe is arranged in an inner cavity of the drainage pipe, the water outlet hole is formed in the outer surface of one end of the water containing pipe, the reset spring is arranged at the lower end of the water containing pipe, and the atomization drainage hole is formed in one end of the drainage pipe;

the drain pipe is communicated with the cylindrical water leakage block, the water outlet hole is matched with the atomization drain hole, and the floating block is matched with the water leakage hole;

when the floating block is matched with the water leakage hole, the autorotation image shooting device starts to rotate, an image shot by the autorotation image shooting device is conveyed to a related department through the control box, and when a reference object in a picture shot by the autorotation image shooting device is different from a reference object in a picture shot by a previous picture, an alarm can trigger an alarm.

Preferably, the driving motor is installed on the upper end surface of the base, one side output end of the driving motor is sleeved with the fixing component, the upper end of the fixing component is provided with the first conical gear, one end of the first conical gear is meshed with the second conical gear, a circular connecting block is arranged on the outer side surface of the second conical gear and fixed on the inner wall surface of the monitoring support frame, a groove is formed in the outer side surface of the circular connecting block, the groove formed in the outer side surface of the circular connecting block is matched with the second conical gear, one side of the upper end of the second conical gear is meshed with the third conical gear, the upper end of the moving component is provided with the control box, and the upper end of the control box is provided with the solar panel.

Preferably, the fixed subassembly is including first threaded rod, first circular lifting block, connecting rod and dead lever, be provided with first circular lifting block on the outside surface of first threaded rod, be provided with a plurality of connecting rod on the outside surface of first circular lifting block, every the dead lever is installed to the lower extreme of connecting rod.

Preferably, the first threaded rod is sleeved on the outer side surface of one side output end of the driving motor, the driving motor is installed in an inner cavity of the monitoring support frame, the first conical gear is sleeved on the outer side surface of the upper end of the first threaded rod, a plurality of holes are formed in the surface of the base, and the holes formed in the surface of the base are matched with the fixing rods.

Preferably, the movable assembly comprises a second threaded rod, a second circular lifting block, rectangular connecting rods, rectangular supporting rods and sliding wheels, wherein the second circular lifting block is arranged on the outer side surface of the second threaded rod, a plurality of rectangular connecting rods are arranged on the outer side surface of the second circular lifting block, each rectangular supporting rod is arranged at the lower end of each rectangular connecting rod, and the sliding wheels are arranged on the lower end surface of each rectangular supporting rod.

Preferably, the lower end surface of the second threaded rod is sleeved with a third bevel gear, the lower end surface of the monitoring support frame is provided with a first chute and a second chute, the first chute arranged on the lower end surface of the monitoring support frame is matched with the connecting rod, and the second chute arranged on the lower end surface of the monitoring support frame is matched with the rectangular connecting rod.

Compared with the prior art, the invention has the advantages that:

1. according to the invention, when the rainwater collected by the collecting cavity is larger than the water yield of the drainage assembly, the floating block can move upwards until the rainwater is matched with the water leakage hole, at the moment, the autorotation image shooting device can carry out image shooting operation, and the shot image can be conveyed to a related department through the control box, so that a worker can determine whether to trigger an alarm according to whether the position of a reference object in the image changes, and the worker can observe the data content in the image in real time, thereby improving the timeliness and the accuracy of information to a certain extent, reducing the time interval of information difference to a certain extent, judging whether to trigger an alarm according to the image data, and avoiding the situation that warning cannot be timely caused due to the information difference, and further reducing the economic loss caused by geological disasters to a certain extent.

2. According to the invention, the fixed component is driven to move downwards through the rotation of the driving motor, so that the movable component is driven to move upwards, and the fixed component moves downwards to play a role in fixing the monitoring equipment, so that the fixed component and the movable component play a linkage role, when the monitoring equipment needs to be removed, the driving motor is started to enable the movable component to move downwards, and the fixed component is enabled to move upwards, so that the monitoring equipment can be detached, and meanwhile, the monitoring equipment is moved through the sliding block, so that the transportation time of workers is saved to a certain extent, and meanwhile, convenience is enhanced to a certain extent.

3. According to the invention, the fixing rod is driven to move downwards by the rotation of the driving motor, and penetrates through the holes formed in the surface of the base, so that the effect of fixing the monitoring equipment is achieved, the operation of manually fixing the monitoring equipment by a worker is not needed, the equipment installation time of the worker is effectively reduced, the time and effort are saved to a certain extent, and meanwhile, the working efficiency is improved on a certain basis.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic view of a portion of the structure of the present invention;

FIG. 3 is an enlarged schematic view of the structure of FIG. 2A according to the present invention;

FIG. 4 is a schematic view of a rain monitoring assembly according to the present invention;

FIG. 5 is a schematic view of a drain assembly according to the present invention;

fig. 6 is a schematic structural view of a fixing assembly according to the present invention.

The reference numerals in the figures illustrate: 1. monitoring the supporting frame; 2. a self-rotation image shooting device; 3. a fixing frame; 4. a rainfall monitoring component; 401. a collection cavity; 402. conical connecting blocks; 403. a water leakage hole; 404. a cylindrical water leakage block; 405. a water leakage groove; 406. a floating block; 407. a drainage assembly; 408. a drain pipe; 409. a water containing tube; 410. a water outlet hole; 411. a return spring; 412. an atomization drainage hole; 5. an alarm; 6. a lighting lamp; 7. a base; 8. a driving motor; 9. a fixing assembly; 901. a first threaded rod; 902. a first circular lifting block; 903. a connecting rod; 904. a fixed rod; 10. a first bevel gear; 11. a second bevel gear; 12. a circular connecting block; 13. a third bevel gear; 14. a moving assembly; 1401. a second threaded rod; 1402. a second circular lifting block; 1403. a rectangular connecting rod; 1404. a rectangular support bar; 1405. a sliding wheel; 15. a control box; 16. a solar cell panel.

Detailed Description

Examples: referring to fig. 1, a geological disaster monitoring device includes a monitoring support 1, an autorotation image shooting device 2 is installed at the upper end of the monitoring support 1, a fixing frame 3 is arranged at one end of the monitoring support 1, a rainfall monitoring component 4 is arranged at one end of the fixing frame 3, an alarm 5 is arranged at the lower end of the rainfall monitoring component 4, an illuminating lamp 6 is arranged at one end of the alarm 5, a base 7 is arranged at the lower end of the monitoring support 1, a fixing component 9 is arranged at the upper end of the base 7, and a moving component 14 is arranged at the upper end of the fixing component 9;

referring to fig. 4, the rainfall monitoring assembly 4 includes a collecting cavity 401, a conical connecting block 402, a water leakage hole 403, a cylindrical water leakage block 404, a floating block 406, a water leakage groove 405 and a water drainage assembly 407, wherein the conical connecting block 402 is arranged at the upper end of the collecting cavity 401, the water leakage hole 403 is arranged at the lower end of the conical connecting block 402, the cylindrical water leakage block 404 is arranged in the collecting cavity 401, the floating block 406 is arranged in the cylindrical water leakage block 404, the water leakage groove 405 is arranged on the outer side surface of the cylindrical water leakage block 404, the water leakage groove 405 plays a guiding role, meanwhile, the floating block 406 is positioned at the bottom of the water leakage groove 405, the sealing water drainage assembly 407 is played, when the floating block 406 moves upwards along the water leakage groove 405, rainwater collected in the collecting cavity 401 is conveyed into the water drainage assembly 407 through the water leakage groove 405, when the floating block 406 moves to the top end of the water leakage groove 405, the floating block 406 is matched with the water leakage hole 403, the effect of sealing the collecting cavity 401 is played, and the water drainage assembly 407 is arranged at the lower end of the floating block 406;

referring to fig. 5, as a further scheme of the present invention: the water draining assembly 407 comprises a water draining pipe 408, a water containing pipe 409, a water outlet hole 410, a reset spring 411 and an atomization water draining hole 412, wherein the water containing pipe 409 is arranged in the inner cavity of the water draining pipe 408, the water outlet hole 410 is arranged on the outer side surface of one end of the water containing pipe 409, the reset spring 411 is arranged at the lower end of the water containing pipe 409, and the atomization water draining hole 412 is arranged at one end of the water draining pipe 408;

the drain pipe 408 is communicated with the cylindrical water leakage block 404, the water outlet hole 410 is matched with the atomization drain hole 412, and the floating block 406 is matched with the water leakage hole 403;

when the floating block 406 coincides with the water leakage hole 403, the rotation image shooting device 2 starts to rotate, the image shot by the rotation image shooting device 2 is conveyed to a related department through the control box 15, and when the reference object in the picture shot by the rotation image shooting device 2 is different from the reference object in the picture shot by the previous picture, the alarm 5 can trigger an alarm.

Specifically, rainwater is conveyed into the collection cavity 401 through the conical connecting block 402, the floating block 406 is driven to move upwards along the water leakage groove 405 along with the increasing amount of the rainwater collected in the collection cavity 401, the floating block 406 is driven to move upwards along with the increasing amount of the rainwater collected in the collection cavity 401, the rainwater collected in the collection cavity 401 is conveyed into the inner cavity of the water drainage pipe 408 through the water leakage groove 405, the water storage amount in the water storage pipe 409 is increased along with the increasing amount of the water storage amount in the water storage pipe 409, so that the water storage pipe 409 is driven to move downwards, the water in the water storage pipe 409 is driven to move downwards until the water outlet hole 410 is matched with the atomization water outlet hole 412, at the moment, if the rainwater collected in the collection cavity 401 is larger than the water outlet amount of the water drainage assembly 407, the floating block 406 is driven to move upwards along with the increasing amount of the collected rainwater until the floating block 406 is matched with the water leakage hole 403, the rotation image shooting device 2 starts to rotate, the image shooting operation is performed, the image of the rotation image shooting device 2 is conveyed into the related image through the control box 15, the image shooting device 2 is triggered to the image in the reference position of the image shooting device 2, and the image is not triggered to be the image in the reference image shooting device, and the image is not corresponding to the image in the image taking device, and the image is not displayed in the reference device, and the image device is not 5 is triggered;

when the rainwater collected by the collecting cavity 401 is larger than the water yield of the water draining assembly 407, the floating block 406 moves upwards until the floating block is matched with the water draining hole 403, at the moment, the autorotation image shooting device 2 can perform image shooting operation, and the shot image can be conveyed to a related department through the control box 15, so that a worker can determine whether to trigger an alarm according to whether the position of a reference object in the image changes or not, the worker can observe the data content in the image in real time, timeliness and accuracy of information are improved to a certain extent, the time interval between information differences is reduced to a certain extent, and whether to trigger an alarm is judged according to the image data, so that the situation that warning cannot be timely caused due to the information difference is avoided, and economic loss caused by geological disasters is reduced to a certain extent.

Referring to fig. 3, as a further scheme of the present invention: the upper end surface of base 7 is last to install driving motor 8, fixed subassembly 9 has been cup jointed to driving motor 8's one side output, fixed subassembly 9's upper end is provided with first conical gear 10, first conical gear 10's one end meshing has second conical gear 11, be provided with circular connecting block 12 on the outside surface of second conical gear 11, circular connecting block 12 is fixed on the inner wall surface of monitoring support frame 1, and be provided with the recess on the outside surface of circular connecting block 12, and the recess that sets up on the outside surface of circular connecting block 12 agrees with second conical gear 11 mutually, and the upper end one side meshing of second conical gear 11 has third conical gear 13, and the upper end of removal subassembly 14 is provided with control box 15, the upper end of control box 15 is provided with solar cell panel 16.

Referring to fig. 6, as a further scheme of the present invention: the fixing assembly 9 comprises a first threaded rod 901, a first circular lifting block 902, connecting rods 903 and fixing rods 904, wherein the first circular lifting block 902 is arranged on the outer side surface of the first threaded rod 901, a plurality of connecting rods 903 are arranged on the outer side surface of the first circular lifting block 902, and the fixing rods 904 are arranged at the lower ends of the connecting rods 903.

Specifically, the rotation through driving motor 8 can drive the rotation of first threaded rod 901 to drive first circular elevating block 902 along first threaded rod 901 downwardly moving, then drive dead lever 904 downwardly moving, and let dead lever 904 run through the hole that sets up on the base 7 surface, thereby reach the effect of fixed monitoring facilities, need not the artificial operation of fixed monitoring facilities that carries out of staff like this, and then the effectual time of having reduced staff erection equipment, still played time-saving and effort-saving to a certain extent, still improved work efficiency on certain basis simultaneously.

As a further scheme of the invention: the first threaded rod 901 is sleeved on the outer side surface of one side output end of the driving motor 8, the driving motor 8 is installed in the inner cavity of the monitoring support frame 1, the first conical gear 10 is sleeved on the outer side surface of the upper end of the first threaded rod 901, a plurality of holes are formed in the surface of the base 7, and the holes formed in the surface of the base 7 are matched with the fixing rods 904.

Referring to fig. 2, as a further scheme of the present invention: the moving assembly 14 comprises a second threaded rod 1401, a second circular lifting block 1402, rectangular connecting rods 1403, rectangular supporting rods 1404 and sliding wheels 1405, wherein the second circular lifting block 1402 is arranged on the outer side surface of the second threaded rod 1401, a plurality of rectangular connecting rods 1403 are arranged on the outer side surface of the second circular lifting block 1402, the lower end of each rectangular connecting rod 1403 is provided with a rectangular supporting rod 1404, and the sliding wheels 1405 are arranged on the lower end surface of each rectangular supporting rod 1404.

Specifically, the fixed assembly 9 can be driven to move downwards through the rotation of the driving motor 8, so that the movable assembly 14 is driven to move upwards, the fixed assembly 9 moves downwards to play a role in fixing the monitoring equipment, the fixed assembly 9 and the movable assembly 14 play a role in linkage, when the monitoring equipment needs to be removed, the driving motor 8 is started to enable the movable assembly 14 to move downwards, the fixed assembly 9 is enabled to move upwards, the monitoring equipment can be detached, meanwhile, the monitoring equipment is moved through the sliding wheel 1405, so that the transportation time of workers is saved to a certain extent, and convenience is enhanced to a certain extent.

As a further scheme of the invention: the third bevel gear 13 has been cup jointed on the lower extreme surface of second threaded rod 1401, is provided with first spout and second spout on the lower extreme surface of monitoring support frame 1, and the first spout that sets up on the lower extreme surface of monitoring support frame 1 agrees with connecting rod 903, and the second spout that sets up on the lower extreme surface of monitoring support frame 1 agrees with rectangular connecting rod 1403.

Working principle: firstly, the geological disaster monitoring equipment is moved to the area of the equipment to be installed by utilizing the sliding wheel 1405, at the moment, the driving motor 8 is started, the first threaded rod 901 is driven to rotate along with the rotation of the driving motor 8, so that the first circular lifting block 902 is driven to move downwards along the first threaded rod 901, the fixed rod 904 is driven to move downwards, the fixed rod 904 penetrates through a hole arranged on the surface of the base 7, the effect of fixing the monitoring equipment is achieved, the first threaded rod 901 rotates and simultaneously drives the first conical gear 10 to rotate, the rotation of the first conical gear 10 drives the second conical gear 11 to rotate, the third conical gear 13 is driven to rotate anticlockwise, the rotation of the third conical gear 13 drives the second threaded rod 1401 to rotate anticlockwise, so that the second circular lifting block 1402 is driven to move upwards along the second threaded rod 1401, the upward movement of the second round lifting block 1402 drives the rectangular connecting rod 1403 to move upwards, so as to drive the rectangular supporting rod 1404 to move upwards, and further drive the sliding wheel 1405 to move upwards, so that after the monitoring equipment is installed, the solar cell panel 16 converts light energy into electric energy and stores the electric energy into the control box 15, thereby providing energy support for the monitoring equipment, when raining, rainwater is conveyed into the collection cavity 401 through the conical connecting block 402, the floating block 406 is driven to move upwards along the water leakage groove 405 along with the increasing amount of rainwater collected in the collection cavity 401, the floating block 406 moves upwards, the rainwater collected in the collection cavity 401 is conveyed into the inner cavity of the water leakage groove 405, and when the rainwater is conveyed into the water storage pipe 409 from the water leakage groove 408, the water storage amount in the water storage pipe 409 is increased, a pressure is generated to the reset spring 411, so as to drive the water containing tube 409 to move downwards until the water outlet 410 is matched with the atomized water outlet 412, water in the water containing tube 409 is discharged to the outside through the atomized water outlet 412, at this time, if the rainwater collected by the collecting cavity 401 is greater than the water outlet of the water discharging assembly 407, the floating block 406 moves upwards along with the increase of the collected rainwater until the floating block 406 is matched with the water outlet 403, the autorotation image shooting device 2 starts to rotate at this time, and performs image shooting operation, and an image shot by the autorotation image shooting device 2 is conveyed to a related department through the control box 15, and when the positions of a reference object in a picture shot by the autorotation image shooting device 2 and a reference object in a picture shot by a previous picture are different, the alarm 5 triggers an alarm, so that an alarm function is achieved, and all operations are finished.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present invention, and are not intended to limit the invention, and that various changes and modifications may be made therein without departing from the spirit and scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. Geological disaster monitoring equipment, including monitoring support frame (1), its characterized in that: the automatic rain monitoring device comprises a monitoring support frame (1), wherein an autorotation image shooting device (2) is arranged at the upper end of the monitoring support frame (1), a fixing frame (3) is arranged at one end of the monitoring support frame (1), a rain monitoring component (4) is arranged at one end of the fixing frame (3), an alarm (5) is arranged at the lower end of the rain monitoring component (4), an illuminating lamp (6) is arranged at one end of the alarm (5), a base (7) is arranged at the lower end of the monitoring support frame (1), a fixing component (9) is arranged at the upper end of the base (7), and a moving component (14) is arranged at the upper end of the fixing component (9);

the rainfall monitoring assembly (4) comprises a collecting cavity (401), a conical connecting block (402), a water leakage hole (403), a cylindrical water leakage block (404), a floating block (406), a water leakage groove (405) and a water drainage assembly (407), wherein the conical connecting block (402) is arranged at the upper end of the collecting cavity (401), the water leakage hole (403) is arranged at the lower end of the conical connecting block (402), the cylindrical water leakage block (404) is arranged in the collecting cavity (401), the floating block (406) is arranged in the cylindrical water leakage block (404), the water leakage groove (405) is arranged on the outer side surface of the cylindrical water leakage block (404), and the water drainage assembly (407) is arranged at the lower end of the floating block (406);

the drainage assembly (407) comprises a drainage pipe (408), a water containing pipe (409), a water outlet hole (410), a reset spring (411) and an atomization drainage hole (412), wherein the water containing pipe (409) is arranged in an inner cavity of the drainage pipe (408), the water outlet hole (410) is arranged on the outer surface of one end of the water containing pipe (409), the reset spring (411) is arranged at the lower end of the water containing pipe (409), and the atomization drainage hole (412) is arranged at one end of the drainage pipe (408);

the drain pipe (408) is communicated with the cylindrical water leakage block (404), the water outlet hole (410) is matched with the atomization drain hole (412), and the floating block (406) is matched with the water leakage hole (403);

rainwater is conveyed into the collecting cavity (401) through the conical connecting block (402), the collecting cavity (401) is driven to move upwards along the water leakage groove (405) by more and more rainwater collected in the collecting cavity (401), the floating block (406) moves upwards, the rainwater collected in the collecting cavity (401) can be conveyed into the inner cavity of the water drainage pipe (408) through the water leakage groove (405), when the water storage capacity in the water storage pipe (409) is increased along with the increase of the water storage capacity in the water storage pipe (409), a pressure is generated on the reset spring (411) so as to drive the water storage pipe (409) to move downwards, until the water in the water storage pipe (409) is discharged to the outside through the water atomization hole (412) when the water outlet hole (410) is matched with the water atomization hole (412), the image capturing device (403) is rotated to the image capturing device (2) along with the increase of the water storage capacity in the water storage pipe (409), if the collecting cavity (401) is larger than the water drainage assembly (403) is conveyed into the image capturing device (406), the image capturing device (2) is rotated along with the rotation of the image capturing device (406), the image capturing device (2) is rotated up until the image capturing device (406) is rotated, when the positions of the reference objects in the pictures shot by the autorotation image shooting device (2) are different from those of the reference objects in the pictures shot by the previous pictures, the alarm (5) can trigger an alarm so as to play a role of warning, when the rainwater collected by the collection cavity (401) is larger than the water yield of the water draining assembly (407), the floating block (406) can move upwards until the floating block is matched with the water leaking hole (403), at the moment, the autorotation image shooting device (2) can perform image shooting operation, and the shot images can be conveyed to related departments through the control box (15).

2. A geological disaster monitoring device according to claim 1, wherein: the solar cell module is characterized in that a driving motor (8) is mounted on the upper end surface of the base (7), a fixing component (9) is sleeved at one side output end of the driving motor (8), a first conical gear (10) is arranged at the upper end of the fixing component (9), a second conical gear (11) is meshed at one end of the first conical gear (10), a circular connecting block (12) is arranged on the outer side surface of the second conical gear (11), a third conical gear (13) is meshed at one side of the upper end of the second conical gear (11), a control box (15) is arranged at the upper end of the moving component (14), and a solar cell panel (16) is arranged at the upper end of the control box (15).

3. A geological disaster monitoring device according to claim 1, wherein: the fixing assembly (9) comprises a first threaded rod (901), a first circular lifting block (902), connecting rods (903) and fixing rods (904), wherein the first circular lifting block (902) is arranged on the outer side surface of the first threaded rod (901), a plurality of connecting rods (903) are arranged on the outer side surface of the first circular lifting block (902), and each connecting rod (903) is provided with a fixing rod (904) at the lower end.

4. A geological disaster monitoring device according to claim 3, characterized in that: the utility model discloses a drive motor, including drive motor (8), first threaded rod (901) cup joints on the outside surface of output of drive motor (8) one side, drive motor (8) are installed in the inner chamber of monitoring support frame (1), and first conical gear (10) cup joints on the upper end outside surface of first threaded rod (901), be provided with a plurality of hole on the surface of base (7), the hole that sets up on the surface of base (7) agrees with dead lever (904).

5. A geological disaster monitoring device according to claim 1, wherein: the movable assembly (14) comprises a second threaded rod (1401), a second circular lifting block (1402), rectangular connecting rods (1403), rectangular supporting rods (1404) and sliding wheels (1405), wherein the second circular lifting block (1402) is arranged on the outer side surface of the second threaded rod (1401), a plurality of rectangular connecting rods (1403) are arranged on the outer side surface of the second circular lifting block (1402), each rectangular supporting rod (1403) is provided with a rectangular supporting rod (1404) at the lower end, and the sliding wheels (1405) are arranged on the lower end surface of the rectangular supporting rods (1404).

6. A geological disaster monitoring device according to claim 5, wherein: a third bevel gear (13) is sleeved on the lower end surface of the second threaded rod (1401).