Geological disaster monitoring equipment protection mechanism
By designing protective mechanisms, the geological disaster monitoring device's impact resistance and stability have been enhanced, solving the problem of damage during field use and achieving comprehensive protection and convenient mobility.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- ZHEJIANG HUADONG SURVEYING MAPPING & GEOINFORMATION
- Filing Date
- 2025-05-14
- Publication Date
- 2026-06-19
Smart Images

Figure CN224385826U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of geological disaster monitoring technology, specifically to a protective mechanism for geological disaster monitoring equipment. Background Technology
[0002] Geological disasters refer to geological processes or phenomena that cause loss of human life and property and damage to the environment, formed under the influence of natural or human factors. When monitoring geological disasters such as debris flows and landslides, the monitoring device is usually fixed directly to the ground using a mounting bracket, and then the mountain environment is monitored.
[0003] In existing geological hazard monitoring devices, the devices are typically fixed directly to the ground in the field using a mounting bracket. However, when a geological hazard occurs or an animal attacks the device, the device itself, being exposed to the ground, may be damaged by external forces, thus affecting its usability and reducing its applicability. Utility Model Content
[0004] The purpose of this utility model is to provide a geological disaster monitoring equipment protection mechanism that is windproof, rainproof, provides all-round protection, has a stable structure, and is easy to move.
[0005] To achieve the above objectives, this utility model employs the following technical solution:
[0006] A protective mechanism for geological disaster monitoring equipment includes a base plate, fixed frames disposed on the base plate, a fixed box between the fixed frames, and a protective structure. The monitoring body is placed inside the fixed box, and the protective structure is connected to one side of the fixed frame by a support column, thereby protecting the fixed box inside.
[0007] Furthermore, the protective structure is provided with two parts, upper and lower, on one side of the fixed frame. Each protective structure is connected and fixed to the left and right fixed frames through support columns at both ends.
[0008] Furthermore, the protective structure includes an outward-facing protective plate, an inward-facing fixed rod, and several buffer units between the protective plate and the fixed rod. The fixed rod is connected and fixed to the support column. The buffer unit includes a buffer column fixed to the inner side of the protective plate and a connecting column fixed to the inner side of the fixed rod. The connecting column is inserted into the buffer column, and a shock-absorbing spring is provided between the connecting column and the inner bottom of the buffer column.
[0009] Furthermore, a heat dissipation plate is provided on the top of the monitoring body, and a dustproof net is provided on the surface of the heat dissipation plate.
[0010] Furthermore, the fixed housing is connected to the fixed heat sink and the monitoring sensor via a connecting rod. The monitoring sensor has a built-in signal transceiver, and the monitoring sensor, the signal transceiver, and the monitoring body are electrically connected.
[0011] Furthermore, the bottom plate is provided with auxiliary structures at its ends. The auxiliary structures include anchor rods, connecting bases, screw rods and rotating handles connected in sequence from bottom to top. The screw rods are screwed into corresponding holes at the ends of the bottom plate, and the anchor rods can be inserted into the soil.
[0012] Furthermore, the base plate is provided with a fixing structure on opposite sides, the fixing structure including two fixing plates that clamp the edges of the base plate, and the fixing plates are fastened by bolts.
[0013] Furthermore, a fixed base is also provided on the lower side of the base plate, and the outer surface of the fixed base is covered with an anti-slip pad.
[0014] Furthermore, it also includes a rainproof cover plate located on top, which is connected and fixed to the fixed box body via a connecting bracket.
[0015] Compared with the prior art, this utility model has the following advantages:
[0016] This utility model discloses a protective mechanism for geological disaster monitoring equipment, which is windproof and rainproof, provides all-around protection, has a stable structure, and is easy to move. Specifically, by setting up a fixed frame, a fixed box, a support column, and a protective structure, when there is an external impact, the protective plate compresses the shock-absorbing spring inside the buffer column, causing the connecting column to slide back and forth in the inner groove of the buffer column through the shock-absorbing spring, thereby reducing the impact force and protecting the front and back of the monitoring equipment from impact damage. The support column further enhances the impact resistance of the fixed frame's sides. By setting two fixing plates and bolts on the edge of the base plate, the device can be fixed in an external fixed position, and the auxiliary structure can be inserted into the ground to further increase the stability of the device during use. Attached Figure Description
[0017] Figure 1 This is a schematic diagram of the overall structure of this utility model.
[0018] Figure 2 This is a structural schematic diagram of the rainproof cover of this utility model.
[0019] Figure 3 This is a schematic diagram of the protective structure of this utility model.
[0020] Figure 4 This is a schematic diagram of the structure of the buffer unit of this utility model.
[0021] Figure 5 This is a schematic diagram of the internal structure of the unprotected structure of this utility model.
[0022] Reference numerals: 1. Base plate; 2. Fixing frame; 3. Fixing box; 4. Protective structure; 401. Fixing rod; 402. Connecting column; 403. Buffer column; 404. Shock-absorbing spring; 405. Protective plate; 5. Support column; 6. Heat dissipation plate; 7. Dustproof net; 8. Connecting rod; 9. Monitoring body; 10. Monitoring sensor; 11. Signal transceiver; 12. Fixing plate; 13. Rainproof cover; 14. Bolt; 15. Auxiliary structure; 151. Rotating handle; 152. Screw; 153. Connecting base; 154. Anchor bolt; 16. Fixing base; 17. Anti-slip pad; 18. Connecting bracket. Detailed Implementation
[0023] The embodiments of this utility model will now be described in further detail with reference to the accompanying drawings.
[0024] For specific embodiments of this utility model, please refer to the appendix. Figures 1-5 As shown.
[0025] A protective mechanism for geological disaster monitoring equipment includes a base plate 1, fixed frames 2 disposed on the base plate 1, a fixed box 3 between the fixed frames 2, and a protective structure 4.
[0026] The monitoring body 9 is placed inside the fixed housing 3. The fixed housing 3 is connected to the fixed heat sink 6 and the monitoring sensor 10 via the connecting rod 8. The heat sink 6 is located above the monitoring body 9 and is covered with heat dissipation holes. A dustproof net 7 is provided on the surface of the heat sink 6. The monitoring sensor 10 has a built-in signal transceiver 11. The monitoring sensor 10 and the signal transceiver 11 are electrically connected to the monitoring body 9. The monitoring sensor 10 can monitor the surrounding geological conditions and transmit the collected data to the monitoring body 9. The monitoring body 9 processes the collected data and transmits it to the data center via the signal transceiver 11, so that staff can understand the surrounding geological conditions at any time.
[0027] The fixed frame 2 is connected to the fixed protective structure 4 on one side via a support column 5, thereby protecting the fixed box 3 within it. The protective structure 4 has two parts, upper and lower, on one side of the fixed frame 2. Each protective structure 4 is connected and fixed to the left and right fixed frames 2 via support columns 5 at both ends. Further, the protective structure 4 includes an outward-facing protective plate 405, an inward-facing fixed rod 401, and several buffer units between the protective plate 405 and the fixed rod 401. The protective plate 405 is made of alloy material. The fixed rod 401 is connected and fixed to the support column 5. The buffer unit includes a buffer column 403 fixed to the inner side of the protective plate 405 and a connecting column 402 fixed to the inner side of the fixed rod 401. The connecting column 402 is inserted into the buffer column 403, and a shock-absorbing spring 404 is provided between the connecting column 402 and the inner bottom of the buffer column 403. When the device is subjected to external impact, the protective plate 405 compresses the shock-absorbing spring 404 inside the buffer column 403, causing the connecting column 402 to slide back and forth inside the buffer column 403 under the action of the shock-absorbing spring 404, thereby reducing the impact force and protecting the front and back of the monitoring body 9 from impact; while the support column 5 further enhances the impact resistance of the side of the fixing frame 2.
[0028] The base plate 1 has auxiliary structures 15 at its ends. Each auxiliary structure 15 includes, from bottom to top, an anchor rod 154, a connecting base 153, a screw rod 152, and a rotating handle 151. The screw rod 152 is screwed into a corresponding hole at the end of the base plate 1, and the anchor rod 154 can be inserted into the ground. In actual operation, the rotating handle 151 drives the screw rod 152 to rotate in the corresponding hole of the base plate 1, thereby driving the connecting base 153 to move towards the ground until the anchor rod 154 is inserted into the ground for stability. Furthermore, the base plate 1 has fixing structures on opposite sides. Each fixing structure includes two fixing plates 12 that clamp the edges of the base plate 1. The fixing plates 12 are fastened with bolts 14. In actual operation, the two fixing plates 12 are inserted into the slots of the two fixing plates 12 to the required installation position, and then the external fasteners are locked and fixed between the two fixing plates 12 with bolts 14.
[0029] A fixed base 16 is also provided on the lower side of the base plate 1, and an anti-slip pad 17 is wrapped around the outer surface of the fixed base 16. When the device is not fixed, the fixed base 16 can improve the load-bearing capacity of the base plate 1, and the anti-slip pad 17 reduces the device from moving significantly, thereby affecting the internal components of the equipment.
[0030] The device also includes a rainproof cover 13 on top, which is connected and fixed to the fixed housing 3 via a connecting bracket 18. The rainproof cover 13 reduces or prevents rainwater from entering the fixed housing 3 and damaging the internal components of the monitoring body 9.
[0031] The working principle of this utility model is as follows: the protective plate 405 compresses the shock-absorbing spring 404 inside the buffer column 403, causing the connecting column 402 to slide back and forth within the buffer column 403 via the shock-absorbing spring 404, thereby reducing the impact force on the front and back of the equipment and protecting the monitoring body 9. The support column 5 further enhances the impact resistance of the side of the fixing frame 2. When installing this device, the slot on the fixing plate 12 is inserted into the required installation position, and then the bolt 14 is passed through the external fixing part that is inserted into the slot. The bolt 14 is tightened to make the two fixing plates 12 firmly fixed to the external fixing part. Then, the auxiliary structure 15 is inserted into the ground. By rotating the handle 151, the screw 152 is rotated in the corresponding hole of the base plate 1, thereby moving the connecting base 153 towards the ground, so that the anchor rod 154 on the lower side of the connecting base 153 is inserted. The device is further stabilized by being buried in the ground; the heat dissipation plate 6 accelerates air exchange within the fixed housing 3, thereby dissipating heat from the monitoring body 9 and reducing the impact of excessive temperature on its operation; the dustproof net 7 reduces the entry of external dust into the fixed housing 3; the monitoring sensor 10 monitors the surrounding geological conditions and transmits the collected data to the monitoring body 9, which processes the data and transmits it to the data center via the signal transceiver 11, allowing staff to monitor the surrounding geological conditions at any time; the fixed base 16 and anti-slip pad 17, when not fixed, enhance the load-bearing capacity of the base plate 1, while the anti-slip pad 17 further reduces significant movement of the device; the rainproof cover 13 reduces or prevents rainwater from entering the fixed housing 3.
[0032] The above description is only a preferred embodiment of the present utility model. It should be noted that for those skilled in the art, several improvements and modifications can be made without departing from the concept of the present utility model, and these improvements and modifications should also be considered within the protection scope of the present utility model.
Claims
1. A geological disaster monitoring device protection mechanism, characterized in that: It includes a base plate, fixed frames on the base plate, fixed boxes between the fixed frames, and a protective structure. The monitoring body is placed inside the fixed box, and the fixed frame is connected to the protective structure through a support column on one side, thereby protecting the fixed box inside.
2. The geological disaster monitoring device protection mechanism according to claim 1, characterized in that: The protective structure has two parts, upper and lower, on one side of the fixed frame. Each protective structure is connected and fixed to the left and right fixed frames through support columns at both ends.
3. The geological disaster monitoring equipment protection mechanism according to claim 1, characterized in that: The protective structure includes an outward-facing protective plate, an inward-facing fixed rod, and several buffer units between the protective plate and the fixed rod. The fixed rod is connected and fixed to the support column. The buffer unit includes a buffer column fixed to the inner side of the protective plate and a connecting column fixed to the inner side of the fixed rod. The connecting column is inserted into the buffer column, and a shock-absorbing spring is provided between the connecting column and the inner bottom of the buffer column.
4. The geological disaster monitoring equipment protection mechanism according to claim 1, characterized in that: The monitoring body is equipped with a heat dissipation plate on top, and the surface of the heat dissipation plate is covered with a dustproof net.
5. A geological disaster monitoring equipment protection mechanism according to claim 4, characterized in that: The fixed housing is connected to the fixed heat sink and the monitoring sensor via a connecting rod. The monitoring sensor has a built-in signal transceiver, and the monitoring sensor, the signal transceiver, and the monitoring body are electrically connected.
6. The geological disaster monitoring equipment protection mechanism according to claim 1, characterized in that: The bottom plate is provided with auxiliary structures at its ends. The auxiliary structures include anchor rods, connecting bases, screw rods and rotating handles connected in sequence from bottom to top. The screw rods are screwed into corresponding holes at the ends of the bottom plate, and the anchor rods can be inserted into the soil.
7. A geological disaster monitoring equipment protection mechanism according to claim 6, characterized in that: The base plate is provided with a fixing structure on opposite sides. The fixing structure includes two fixing plates that clamp the edges of the base plate and are fastened with bolts.
8. A geological disaster monitoring equipment protection mechanism according to claim 1 or 7, characterized in that: The bottom side of the base plate is also provided with a fixed base, and the outer surface of the fixed base is covered with an anti-slip pad.
9. A geological disaster monitoring equipment protection mechanism according to claim 1, characterized in that: It also includes a rainproof cover on top, which is connected and fixed to the fixed box body by a connecting bracket.