Intelligent geological disaster monitoring device
By using ground pins to stabilize the base plate, employing multi-sensor monitoring, adjusting the angle of the adjustment frame, utilizing solar power, and employing a buffer mechanism to absorb vibrations in the geological disaster monitoring device, the problems of sensor accuracy degradation and data interruption in complex environments have been solved, achieving highly stable and efficient monitoring data transmission.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SHANXI COAL GEOLOGY 144 EXPLORATION INST CO LTD
- Filing Date
- 2025-07-22
- Publication Date
- 2026-06-26
AI Technical Summary
Existing intelligent geological disaster monitoring devices suffer from sensor accuracy degradation, data transmission interruption, and equipment damage in complex and harsh environments, affecting the accuracy and reliability of monitoring results.
It employs a ground-mounted pin to stabilize the base plate, is equipped with multiple sensors to monitor ground vibration and tilt in real time, has an adjustable frame connected to the sensing mechanism, and features an adjustable support frame and support plate. It integrates data processing and communication modules, is powered by solar panels, has a buffer mechanism to absorb vibration energy, rollers for easy movement and positioning, and a protective shell to provide all-around protection.
It improved the stability and data accuracy of monitoring devices, enhanced the accuracy of geological disaster early warning, reduced the risk of equipment damage, and improved deployment efficiency and data real-time performance.
Smart Images

Figure CN224417364U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of geological environment monitoring technology, and in particular to an intelligent geological disaster monitoring device. Background Technology
[0002] Intelligent geological disaster monitoring devices integrate sensor technology, data acquisition and transmission technology, data analysis and processing technology, and intelligent early warning technology. Most geological disaster monitoring devices adopt contact technology, which has problems such as large equipment size, difficult transportation, and complex installation, resulting in high safety risks for on-site personnel. Existing equipment is mostly modular and simple integration, lacking intelligent design, and relies on manual deployment and data transmission, resulting in low monitoring efficiency and poor data real-time performance. Although some equipment adopts GNSS or fiber optic sensing technology, it is difficult to deploy in complex terrain and it is difficult to take into account multi-dimensional parameter monitoring.
[0003] A search revealed Chinese Patent Publication No. CN213749880U, which discloses an intelligent geological disaster monitoring device. The device comprises a main body, an antenna, a button, a charging interface, and an auxiliary fixing mechanism. This utility model utilizes an auxiliary fixing mechanism at the bottom of the main body. When placing the main body, it is first placed into a placement groove, allowing the probe to pass through the groove's inner side. Simultaneously, the main body pushes the clamping plate into a first groove, causing a first torsion spring to deform. The spring's recovery force then pushes the clamping plate to secure the main body, fixing it to the inside of the baffle. The clamping plate is equipped with pads to increase the friction between the clamping plate and the main body of the monitoring instrument, preventing the main body of the monitoring instrument from loosening during use. Finally, the probe is inserted into the soil, so that the support base is located on the ground. The support base provides stable support for the main body of the monitoring instrument through the support feet, preventing the main body of the monitoring instrument from tilting due to external forces, which would reduce the accuracy of the data. However, in the existing intelligent geological disaster monitoring devices, the environment in which geological disasters occur is relatively complex and harsh, and the complex environmental factors in the mining area affect the performance and stability of the monitoring device. The environment causes the sensor accuracy to decrease, data transmission to be interrupted and equipment to be damaged, thereby affecting the accuracy and reliability of the monitoring results. Utility Model Content
[0004] To overcome the above shortcomings, this utility model provides an intelligent geological disaster monitoring device, which aims to improve the problem that the complex and harsh environment in which geological disasters occur leads to decreased sensor accuracy, interrupted data transmission, and equipment damage, thereby affecting the accuracy and reliability of monitoring results.
[0005] To achieve the above objectives, the present invention adopts the following technical solution: an intelligent geological disaster monitoring device, comprising a base plate, a ground needle fixedly connected to the bottom of the outer wall of the base plate, a sensing mechanism fixedly connected to the top of the outer wall of the base plate, an adjustment frame rotatably connected to the outer wall of the sensing mechanism, an adjustment rod fixedly connected to one side of the outer wall of the adjustment frame, a support frame rotatably connected to one end of the outer wall of the adjustment rod, a support plate rotatably connected to the top adjacent side of the top of the support frame, a fixed shell fixedly connected to the top of the outer wall of multiple sensing mechanisms, a monitoring mechanism fixedly connected to the top of the outer wall of the fixed shell, a second fixed plate fixedly connected to the top of the outer wall of the monitoring mechanism, a first tripod rotatably connected to the outer wall of the second fixed plate, a second tripod rotatably connected to the other end of the first tripod, and multiple buffer mechanisms slidably connected to the middle of the inner wall of the base plate, the buffer mechanisms being used to buffer the pressure of the monitoring device.
[0006] The above technical solution involves: a ground-mounted pin deeply embedded in the ground to stabilize the base plate, ensuring device stability and preventing displacement from affecting monitoring data; a sensing mechanism equipped with multiple sensors to monitor ground vibration, displacement, and tilt changes in real time, converting them into electrical or digital signals; an adjustment frame connected to the sensing mechanism, allowing adjustment of the support frame and support plate via an adjustment rod to optimize the monitoring angle and range, adapting to different terrains; a fixed shell protecting the monitoring mechanism, which integrates data processing and communication modules to remotely transmit processed and analyzed monitoring data to a data center; a tripod equipped with solar panels for power supply and an antenna to enhance the signal; and multiple buffer mechanisms on the inner wall of the base plate to absorb and alleviate the pressure on the monitoring device during operation.
[0007] As a further description of the above technical solution:
[0008] The buffer mechanism includes a telescopic rod, which is slidably connected to the middle of the inner wall of the base plate. A spring frame is fixedly connected to the top of the outer wall of the telescopic rod, and a limit plate is rotatably connected to the top of the outer wall of the spring frame. The limit plate is fixedly connected to the top of the outer wall. A clip spring is fixedly connected to one side of the inner wall, and a connecting frame is fixedly connected to the top of the outer wall of the clip spring. A roller is rotatably connected to the front side of the outer wall of the telescopic rod.
[0009] The above technical solution involves the telescopic rod sliding within the base plate, allowing it to move up and down to cope with vertical vibrations. The spring frame slides and rotates within the fixed plate, connecting to the limiting plate. It utilizes elastic elements to absorb vibration energy and reduce displacement. The clamp spring connects the fixed plate and the connecting frame, using elastic deformation to absorb lateral vibrations and enhance stability. The rollers are located on the front side of the telescopic rod, facilitating device movement, support adjustment, and fine-tuning to ensure precise positioning and stability.
[0010] As a further description of the above technical solution:
[0011] A waterproof pad is fixedly connected to the bottom of the outer wall of the monitoring device, and a rotating shaft is threaded around the outer wall of the waterproof pad.
[0012] The above technical solution involves a waterproof pad at the bottom of the monitoring mechanism to protect it from water damage and ensure stable operation. The outer wall of the waterproof pad is connected to a rotating shaft via threads, allowing the monitoring mechanism to flexibly adjust its angle to meet different monitoring needs.
[0013] As a further description of the above technical solution:
[0014] A solar panel is fixedly connected to the top of the outer wall of the second fixing plate, and an antenna is fixedly connected to one side of the top of the second fixing plate.
[0015] The above technical solution involves installing solar panels on fixed plate two, utilizing the photoelectric effect to convert solar energy into electrical energy to power the geological disaster monitoring device. An antenna on top of fixed plate two is responsible for wireless data transmission, sending the processed monitoring data to a data center or monitoring platform.
[0016] As a further description of the above technical solution:
[0017] A buffer pad is fixedly connected to the front side of the outer wall of the telescopic rod, and two bolts are threaded around the top of the buffer pad.
[0018] The above technical solution involves securing the buffer pad to the front of the telescopic pole with two bolts to absorb external impacts and reduce damage to the telescopic pole.
[0019] As a further description of the above technical solution:
[0020] A connecting block is fixedly connected to the front side of the inner wall of the telescopic rod, and multiple bolts are threaded onto the inner wall of the connecting block.
[0021] Through the above technical solution: the connecting block on the inner wall of the telescopic rod is connected to other components through internal threads and bolts. By adjusting the tightness of the bolts, the tightness of the connection can be controlled to ensure a stable connection between components and facilitate disassembly and adjustment to adapt to different working conditions and assembly requirements.
[0022] As a further description of the above technical solution:
[0023] A protective shell is fixedly connected to the outer wall of the fixed shell, and a connection hole is opened in the middle of the inner wall of the support plate.
[0024] The above technical solution provides comprehensive protection by having a protective shell surround the fixed shell, preventing internal components from being damaged by collisions, scratches, and the environment. The connection holes of the support plate facilitate connection with other components, enabling the assembly and coordination of the device.
[0025] As a further description of the above technical solution:
[0026] A protective sleeve is fixedly connected to one side of the outer wall of the adjusting rod, and fixing holes are provided around the outer wall of the protective sleeve.
[0027] The above technical solution provides a protective sleeve for the adjusting rod with fixing holes, which facilitates the fixing of the connecting parts, protects the adjusting rod from friction and collision damage, and ensures the stability and accuracy of the adjusting action.
[0028] This utility model has the following beneficial effects:
[0029] 1. In this utility model, the ground needle penetrates deep into the ground to provide stable support for the device, avoiding the impact of geological activities or external forces on the accuracy of monitoring data. It monitors ground vibration, displacement, and tilt information in real time. The sensing mechanism can quickly capture minute changes in the early stages of earthquakes and landslides and convert them into signals. The adjustment frame is rotatably connected to the sensing mechanism. The position and angle of the support frame and support plate can be adjusted by the adjustment rod to optimize the monitoring angle and range and adapt to different terrains. The fixed shell protects the monitoring mechanism. The device is equipped with a solar panel and antenna to provide power and enhance communication signals. The folding structure reduces the size and improves deployment efficiency. Non-contact installation avoids personnel contact with dangerous areas. The mechanical inclinometer works in conjunction with the vibration base to improve the accuracy of landslide early warning.
[0030] 2. In this utility model, the telescopic rod slides inside the base plate and can move up and down to cope with vertical vibration. The spring frame is rotatably connected to the limiting plate and may be equipped with elastic elements to buffer vibration and reduce device displacement. The clamp spring counteracts the force through elastic deformation during lateral vibration, enhancing stability. The roller is rotatably connected to the outer wall of the telescopic rod, facilitating device movement or adjustment of the support point. During installation or fine-tuning, the telescopic rod moves more smoothly within a certain range, facilitating precise positioning and stable placement of the device. Attached Figure Description
[0031] Figure 1 This is a front view of an intelligent geological disaster monitoring device proposed in this utility model;
[0032] Figure 2 This is a perspective view of an intelligent geological disaster monitoring device proposed in this utility model;
[0033] Figure 3 This is a partial structural schematic diagram of an intelligent geological disaster monitoring device proposed in this utility model;
[0034] Figure 4 This is a partial structural exploded view of an intelligent geological disaster monitoring device proposed in this utility model;
[0035] Figure 5This is a split diagram of the buffer mechanism of an intelligent geological disaster monitoring device proposed in this utility model.
[0036] Legend:
[0037] 1. Base plate; 2. Buffer mechanism; 201. Telescopic rod; 202. Fixing plate one; 203. Spring frame; 204. Limiting plate; 205. Clip spring; 206. Connecting frame; 207. Roller; 3. Ground pin; 4. Sensing mechanism; 5. Adjusting frame; 6. Adjusting rod; 7. Support frame; 8. Support plate; 9. Fixing shell; 10. Monitoring mechanism; 11. Fixing plate two; 12. Tripod one; 13. Tripod two; 14. Waterproof pad; 15. Rotating shaft; 16. Solar panel; 17. Antenna; 18. Buffer pad; 19. Bolt two; 20. Connecting block; 21. Bolt one; 22. Protective shell; 23. Connecting hole; 24. Protective sleeve; 25. Fixing hole. Detailed Implementation
[0038] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.
[0039] Reference Figure 1 , Figure 3 and Figure 4 An embodiment of this utility model provides an intelligent geological disaster monitoring device, comprising a base plate 1, a ground needle 3 fixedly connected to the bottom of the outer wall of the base plate 1, a sensing mechanism 4 fixedly connected to the top of the outer wall of the base plate 1, an adjustment frame 5 rotatably connected to the outer wall of the sensing mechanism 4, an adjustment rod 6 fixedly connected to one side of the outer wall of the adjustment frame 5, a support frame 7 rotatably connected to one end of the outer wall of the adjustment rod 6, a support plate 8 rotatably connected to the top of the support frame 7 adjacent to the top, a fixed shell 9 fixedly connected to the top of the outer wall of multiple sensing mechanisms 4, a monitoring mechanism 10 fixedly connected to the top of the outer wall of the fixed shell 9, a second fixed plate 11 fixedly connected to the top of the outer wall of the monitoring mechanism 10, a first tripod 12 rotatably connected to the outer wall of the second fixed plate 11, a second tripod 13 rotatably connected to the other end of the first tripod 12, multiple buffer mechanisms 2 slidably connected to the middle of the inner wall of the base plate 1, the buffer mechanisms 2 are used to buffer the pressure of the monitoring device, a waterproof pad 14 fixedly connected to the bottom of the outer wall of the monitoring mechanism 10, and a rotating shaft 15 threadedly connected to the outer wall of the waterproof pad 14.
[0040] Specifically, the ground needle 3 is deeply embedded in the ground to stabilize the base plate 1, providing support for the device and preventing displacement from affecting the monitoring data. The sensing mechanism 4 has built-in sensors for acceleration, displacement, and tilt, which can capture ground vibration, displacement, and tilt changes in real time and convert them into electrical or digital signals. The adjustment frame 5 is rotatably connected to the sensing mechanism 4. The position and angle of the support frame 7 and support plate 8 can be adjusted by the adjustment rod 6 to optimize the monitoring angle and range of the sensing mechanism 4 and adapt to different terrains. The fixed shell 9 protects the monitoring mechanism 10. The monitoring mechanism 10 integrates data processing and communication modules, receives data from the sensing mechanism 4, processes, analyzes, and stores it, and then transmits it remotely to the data center via the communication module. The tripod is used to install the solar panels. 16 Power supply and antenna 17 enhance communication signals. Multiple buffer mechanisms 2 are fixed on the inner wall of the base plate 1. The main function of these buffer mechanisms 2 is to absorb and alleviate the pressure generated by the monitoring device in the external environment and during operation. At the same time, a waterproof pad 14 is fixed to the bottom of the outer wall of the monitoring mechanism 10. This waterproof pad 14 can not only protect the monitoring mechanism 10 from water damage, but also ensure that the monitoring mechanism 10 can operate stably in various environments. In order to further enhance its function, the outer wall of the waterproof pad 14 is connected to the rotating shaft 15 by threads. The rotating shaft 15 allows the entire monitoring mechanism 10 to be flexibly adjusted in angle when needed to adapt to different monitoring requirements.
[0041] Reference Figure 1 , Figure 2 and Figure 5 The buffer mechanism 2 includes a telescopic rod 201, which is slidably connected to the middle of the inner wall of the base plate 1. A fixing plate 202 is fixedly connected to the top of the outer wall of the telescopic rod 201. A spring frame 203 is slidably connected to the middle of the inner wall of the fixing plate 202. A limit plate 204 is rotatably connected to the top of the outer wall of the spring frame 203. The limit plate 204 is fixedly connected to the top of the outer wall of the fixing plate 202. A clamp spring 205 is fixedly connected to one side of the inner wall of the fixing plate 202. A connecting frame 206 is fixedly connected to the top of the outer wall of the clamp spring 205. A roller 207 is rotatably connected to the front side of the outer wall of the telescopic rod 201. A buffer pad 18 is fixedly connected to the front side of the outer wall of the telescopic rod 201. Bolts 19 are threaded around the top of the buffer pad 18. A connecting block 20 is fixedly connected to the front side of the inner wall of the telescopic rod 201. Multiple bolts 21 are threadedly connected to the inner wall of the connecting block 20.
[0042] Specifically, the telescopic rod 201 can slide on the inner wall of the base plate 1. When the device is subjected to vertical vibration and impact, it moves up and down. The spring frame 203 slides on the inner wall of the fixed plate 202 and is rotatably connected to the limiting plate 204. The elastic element buffers the vibration energy and reduces the displacement and sway of the device. The clamp spring 205 connects the inner wall of the fixed plate 202 to the connecting frame 206. When the device is subjected to lateral vibration, the elastic deformation offsets the force, enhances buffering and maintains stability. The roller 207 is connected to the front side of the telescopic rod 201. When the device needs to be moved, the support adjusted, or the installation fine-tuned, it assists in moving and adjusting the support. The buffer pad 18 on the front side of the telescopic rod 201 is fastened by bolts 19 around the top. When the device encounters external impact, the buffer pad 18 can effectively buffer and reduce the impact force on the telescopic rod 201. The connecting block 20 on the front side of the inner wall of the telescopic rod 201 can be used to connect other related components by means of internal threads and multiple bolts 21. The tightness of the connection can be adjusted by the tightness of the bolts 21, so as to achieve a stable connection between components and facilitate disassembly and adjustment when necessary to adapt to different working conditions and assembly requirements of the device.
[0043] Reference Figure 1 , Figure 2 and Figure 3 A solar panel 16 is fixedly connected to the top of the outer wall of the second fixing plate 11. An antenna 17 is fixedly connected to one side of the top of the second fixing plate 11. A protective shell 22 is fixedly connected to the four sides of the outer wall of the fixing shell 9. A connection hole 23 is opened in the middle of the inner wall of the support plate 8. A protective sleeve 24 is fixedly connected to one side of the outer wall of the adjusting rod 6. A fixing hole 25 is opened around the outer wall of the protective sleeve 24.
[0044] Specifically, the solar panel 16 on the fixed plate 2 11 uses the photoelectric effect to convert solar energy into electrical energy, providing power support for the entire intelligent geological disaster monitoring device. The antenna 17 on the top side of the fixed plate 2 11 is responsible for signal transmission and reception, transmitting the data processed by the monitoring agency 10 to the data center or monitoring platform via wireless communication. The protective shell 22 connected around the fixed shell 9 can protect the internal components of the fixed shell 9 in all directions, resisting external collisions, scratches and harsh environmental corrosion. The connecting hole 23 in the middle of the support plate 8 can be used to connect other components, realizing the assembly and collaborative work between different parts of the device. The protective sleeve 24 on one side of the adjusting rod 6 has fixing holes 25 around it for easy fixing with connectors. The protective sleeve 24 can protect the adjusting rod 6, preventing the adjusting rod 6 from being damaged by friction and collision during the adjustment process, and also helps to maintain the stability and accuracy of the adjusting rod 6's adjustment action.
[0045] Working Principle: The ground needle 3 penetrates deep into the ground, firmly fixing the base plate 1 to the ground in the monitoring area, providing stable support for the entire device and preventing displacement due to geological activity and external interference, which would affect the accuracy of the monitoring data. As a key component for acquiring geological information, it incorporates multiple sensors, such as acceleration sensors, displacement sensors, and tilt sensors, which can detect ground vibration, displacement, and tilt angle changes in real time. For example, in the early stages of an earthquake or landslide, the ground produces minute vibrations, displacements, and tilts. The sensing mechanism 4 can quickly capture these changes and convert them into electrical or digital signals. The adjustment frame 5 is rotatably connected to the sensing mechanism 4. The angle of the adjustment frame 5 can be changed through the adjustment rod 6, thereby adjusting the position and angle of the support frame 7 and the support plate 8. The monitoring angle and range of the sensor mechanism 4 are optimized to better adapt the monitoring device to different terrains and ensure that the sensor mechanism 4 can effectively perceive key geological information. The fixed shell 9 plays a protective role, protecting the internal monitoring mechanism 10 from the influence of harsh external environments. The monitoring mechanism 10 may integrate data processing modules and communication modules, etc., to receive signals from the sensor mechanism 4, perform preliminary processing, analysis and storage of raw data, and at the same time, remotely transmit the processed data to the data center or monitoring platform through the communication module. It is used to install auxiliary equipment solar panels 16. By reasonably unfolding the tripod and adjusting the angle of the solar panels 16, it can better receive sunlight to power the device. It can also be used to install antennas 17 to improve the communication signal strength and ensure stable data transmission.
[0046] The telescopic rod 201 can slide on the inner wall of the base plate 1. When the device is subjected to vertical vibration or impact, the telescopic rod 201 will move up and down within the base plate 1. The spring frame 203 slides on the inner wall of the fixed plate 202 and is rotatably connected to the limiting plate 204. An elastic element is provided on the spring frame 203. When the telescopic rod 201 moves, the spring frame 203, together with the elastic element, plays a buffering role, absorbing and reducing vibration energy, and reducing the displacement and shaking of the device caused by vibration. The clamp spring 205 is connected between one side of the inner wall of the fixed plate 202 and the connecting frame 206. When the device is subjected to lateral or vertical vibration, the clamp spring 205 will move up and down within the base plate 1. When vibration occurs in other directions, the clamp spring 205 will undergo elastic deformation, using its own elastic force to counteract the force generated by the vibration, further enhancing the buffering effect and maintaining the stability of the device. The roller 207 is rotatably connected to the front side of the outer wall of the telescopic rod 201. When the device needs to be moved to a new position, or when the ground is uneven and the support needs to be adjusted, the roller 207 can assist in moving or adjusting the support point. For example, during the installation or fine-tuning of the device, the roller 207 can make the telescopic rod 201 move more smoothly within a certain range, facilitating the precise positioning and stable placement of the device.
[0047] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.
Claims
1. An intelligent geological disaster monitoring device, comprising a bottom plate (1), characterized in that: A ground pin (3) is fixedly connected to the bottom of the outer wall of the base plate (1). A sensing mechanism (4) is fixedly connected to the top of the outer wall of the base plate (1). An adjustment frame (5) is rotatably connected around the outer wall of the sensing mechanism (4). An adjustment rod (6) is fixedly connected to one side of the outer wall of the adjustment frame (5). A support frame (7) is rotatably connected to one end of the outer wall of the adjustment rod (6). A support plate (8) is rotatably connected to the top of the support frame (7). A fixed shell (9) is fixedly connected to the top of the outer wall of multiple sensing mechanisms (4). A monitoring mechanism (10) is fixedly connected to the top of the outer wall of the fixed shell (9). A second fixed plate (11) is fixedly connected to the top of the outer wall of the monitoring mechanism (10). A first tripod (12) is rotatably connected around the outer wall of the second fixed plate (11). A second tripod (13) is rotatably connected to the other end of the first tripod (12). Multiple buffer mechanisms (2) are slidably connected to the middle of the inner wall of the base plate (1). The buffer mechanism (2) is used to buffer the pressure of the monitoring device. 2.The intelligent geological disaster monitoring device according to claim 1, characterized in that: The buffer mechanism (2) includes a telescopic rod (201), which is slidably connected to the middle of the inner wall of the base plate (1). A fixing plate (202) is fixedly connected to the top of the outer wall of the telescopic rod (201). A spring frame (203) is slidably connected to the middle of the inner wall of the fixing plate (202). A limiting plate (204) is rotatably connected to the top of the outer wall of the spring frame (203). The limiting plate (204) is fixedly connected to the top of the outer wall of the fixing plate (202). A clip spring (205) is fixedly connected to one side of the inner wall of the fixing plate (202). A connecting frame (206) is fixedly connected to the top of the outer wall of the clip spring (205). A roller (207) is rotatably connected to the front side of the outer wall of the telescopic rod (201). 3.The intelligent geological disaster monitoring device according to claim 1, characterized in that: A waterproof pad (14) is fixedly connected to the bottom of the outer wall of the monitoring mechanism (10), and a rotating shaft (15) is threaded around the outer wall of the waterproof pad (14).
4. The intelligent geological disaster monitoring device according to claim 1, characterized in that: A solar panel (16) is fixedly connected to the top of the outer wall of the second fixing plate (11), and an antenna (17) is fixedly connected to one side of the top of the second fixing plate (11). 5.The intelligent geological disaster monitoring device according to claim 2, characterized in that: A buffer pad (18) is fixedly connected to the front side of the outer wall of the telescopic rod (201), and bolts (19) are threaded around the top of the buffer pad (18).
6. The intelligent geological disaster monitoring device according to claim 2, characterized in that: The inner wall front side of the telescopic rod (201) is fixedly connected to a connecting block (20), and the inner wall of the connecting block (20) is threaded with multiple bolts (21).
7. The intelligent geological disaster monitoring device according to claim 1, characterized in that: The outer wall of the fixed shell (9) is fixedly connected with a protective shell (22), and a connection hole (23) is opened in the middle of the inner wall of the support plate (8).
8. The intelligent geological disaster monitoring device according to claim 1, characterized in that: A protective sleeve (24) is fixedly connected to one side of the outer wall of the adjusting rod (6), and fixing holes (25) are provided around the outer wall of the protective sleeve (24).