A folding drilling rig support suitable for steep terrain
By using a ground support system and a drilling angle adjustment system, the problems of center of gravity shift and instability of folding drilling equipment on steep terrain have been solved, realizing the stability of the equipment and flexible adjustment of the drilling angle, ensuring the safety and accuracy of the drilling process.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- POWERCHINA BEIJING ENG CORP
- Filing Date
- 2026-06-03
- Publication Date
- 2026-07-14
AI Technical Summary
Foldable drilling equipment supports are prone to center of gravity shift and instability on steep terrain, increasing the risk of sliding or overturning, and are difficult to adjust to different terrains and drilling requirements.
The system employs a ground support system and a drilling angle adjustment system, including prism blocks, anti-loosening mechanisms, anti-tilting mechanisms, and a drilling angle adjustment system. By enhancing the fastening force and angle adjustment, it ensures the stability of the equipment and the accuracy of the drilling direction.
It effectively prevents equipment from sliding or tilting, ensuring the stability and safety of the drilling process, and allows for angle adjustments to adapt to different terrains and drilling needs.
Smart Images

Figure CN122383232A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of drilling support technology, specifically to a foldable drilling equipment support suitable for steep terrain. Background Technology
[0002] A foldable drilling equipment support is a foldable, portable, and storage support frame, typically used for supporting and stabilizing drilling equipment. The main function of a foldable drilling equipment support is to provide stable support for drilling equipment, ensuring that the equipment remains level and stable during operation, preventing tilting or instability, and thus guaranteeing the accuracy and safety of the drilling process.
[0003] When folding drilling equipment supports are installed on steep terrain, the supports themselves will tilt at a certain angle on the steep slope, causing the center of gravity of the supports and equipment to shift. This shift in the center of gravity reduces the stability of the equipment, and the soil stability on steep slopes is more prone to deformation under the influence of gravity, increasing the risk of equipment sliding or overturning. Furthermore, steep ground is prone to generating greater lateral pressure, especially when the drilling equipment is working. This pressure will intensify the friction and pressure between the supports and the ground, further increasing the risk of support instability. Summary of the Invention
[0004] To address the aforementioned issues, a foldable drilling equipment support suitable for steep terrain is provided. By strengthening the fastening force between the support body and the sampling point through a ground support system, the slippage or tilting of the equipment support when supporting the drilling equipment can be effectively prevented, ensuring the stability of the equipment during drilling. This solves the technical problem that when the foldable drilling equipment support is installed on steep terrain, the center of gravity of the support and the equipment shifts, increasing the risk of instability between the equipment and the support.
[0005] To address the problems of existing technologies, this invention provides a foldable drilling equipment support suitable for steep terrain, comprising a support body, a support rod rotatably mounted on the support body, a chain drive assembly on one side of the support rod, a drilling assembly mounted on the chain drive assembly, a ground support system for increasing the stability of the drilling assembly at sampling points, and a drilling angle adjustment system for adjusting the angle at which the drilling assembly inserts into the ground.
[0006] Preferably, the ground support system includes a prism block, an anti-loosening mechanism, and an anti-tilting mechanism; the prism block is connected to the support body; the anti-loosening mechanism is disposed on the prism block and is used to strengthen the fastening force between the prism block and the sampling point; the anti-tilting mechanism is disposed on the support body and is used to strengthen the fastening force between the support body and the sampling point.
[0007] Preferably, the anti-loosening mechanism includes a clamping plate, a worm gear, and a worm; the clamping plate is rotatably mounted on the prism block; the worm gear is rotatably mounted on the prism block and connected to the clamping plate; the worm is rotatably mounted on the prism block and connected to the worm gear.
[0008] Preferably, the anti-loosening mechanism further includes a first screw, a first connecting pipe, and a first sliding groove; the first screw is rotatably mounted on the prism insert; the first connecting pipe is threadedly connected to the first screw; the first sliding groove is opened on the side of the prism insert near the first connecting pipe, and the first sliding groove is used to cooperate with the first connecting pipe for linear movement.
[0009] Preferably, the first connecting pipe is provided with a first toothed plate and a full toothed disc; the upper end of the first toothed plate is connected to the first connecting pipe, a guide block is connected to one side of the first toothed plate, and a guide groove is provided on the side of the prism insert near the guide block. The guide groove is used to cooperate with the guide block for linear movement; the full toothed disc is rotatably mounted on the prism insert and is connected to the first toothed plate.
[0010] Preferably, the anti-tilt mechanism includes a support plate, a connecting plate, a tapered rod insert, an elastic reset member, and a slot; the support plate is located on the side of the support body away from the drilling assembly; one end of the connecting plate is rotatably located at the lower end of the support plate; one end of the tapered rod insert slides through the left and right sides of the connecting plate; the elastic reset member is sleeved with one end of the tapered rod insert, and both ends of the elastic reset member are connected to the connecting plate and the tapered rod insert, respectively; the slot is located on the side of the support body near the tapered rod insert, and the tapered rod insert is slidably located inside the slot.
[0011] Preferably, the anti-tilt mechanism further includes a slider, a second slide groove, a second screw, a first toothed block, a first storage groove, and a rack; the slider is rotatably mounted on the support plate; the second slide groove is opened on the side of the support body near the slider, and the second slide groove is used to cooperate with the slider for linear movement; the second screw is threadedly connected to the slider; the first toothed block is rotatably mounted on the second screw; the first storage groove is opened on the side of the slider near the first toothed block, and the first toothed block is slidably mounted in the first storage groove; the rack is embedded in the side of the second slide groove near the first toothed block, and the rack is connected to the first toothed block.
[0012] Preferably, the drilling angle adjustment system includes a positioning mechanism and a locking mechanism; the positioning mechanism is disposed on the support body and the support rod, and the positioning mechanism is used to limit the rotation angle of the support rod; the locking mechanism is disposed on the positioning mechanism and the support rod, and the locking mechanism is used to prevent the support rod from loosening after the angle is adjusted.
[0013] Preferably, the positioning mechanism includes a half-tooth disc, a second tooth block, and a second storage groove; the half-tooth disc is connected to the side of the support body near the support rod; the second tooth block is connected to the half-tooth disc; the second storage groove is opened on the side of the support rod near the second tooth block, and the second storage groove is used to store the second tooth block inside the support rod.
[0014] Preferably, the locking mechanism includes a handwheel, a bevel gear assembly, a third screw, a second connecting pipe, and a third sliding groove; the handwheel is rotatably mounted on the support rod; the bevel gear assembly is rotatably mounted on the support rod, and the rotating end of the bevel gear assembly is connected to the end of the handwheel; the third screw is rotatably mounted on the support rod, and the third screw is connected to the rotating end of the bevel gear assembly away from the handwheel; the second connecting pipe is slidably mounted on the support rod, and the second connecting pipe is threadedly connected to the third screw; the third sliding groove is formed on the side of the support rod near the second connecting pipe, and the third sliding groove is used to cooperate with the second connecting pipe for linear movement.
[0015] The advantages of this invention compared to the prior art are: 1. By strengthening the fastening force between the main body of the support and the sampling point through the ground support system, it is possible to effectively prevent the equipment support from sliding or tilting when supporting the drilling equipment, ensuring that the equipment remains stable during drilling. This solves the technical problem that when the center of gravity of the support and the equipment shifts when the folding drilling equipment support is installed on steep terrain, it increases the risk of instability of the equipment and the support.
[0016] 2. By adjusting the tilt angle of the drilling assembly relative to the ground through the drilling angle adjustment system, the drill bit of the drilling assembly can drill at a predetermined angle to adapt to different drilling needs. This solves the technical problem that the folding drilling equipment support is difficult to adjust the drilling angle according to different terrains and drilling requirements. Attached Figure Description
[0017] Figure 1 This is a three-dimensional schematic diagram of the support body, support rods, and connection structure of the foldable drilling equipment support suitable for steep terrain according to the present invention.
[0018] Figure 2 This is a three-dimensional schematic diagram of the support rods and plates and their connection structure of the foldable drilling equipment support suitable for steep terrain according to the present invention.
[0019] Figure 3 This is a three-dimensional schematic diagram of the prism insert and clamping plate and their connection structure of the foldable drilling equipment support suitable for steep terrain according to the present invention.
[0020] Figure 4 This is a three-dimensional schematic diagram of the first screw and the first connecting pipe and their connection structure of the foldable drilling equipment support suitable for steep terrain according to the present invention.
[0021] Figure 5 This is a three-dimensional schematic diagram of the support body, prism insert, and connection structure of the foldable drilling equipment support suitable for steep terrain according to the present invention.
[0022] Figure 6 This invention relates to a foldable drilling equipment support suitable for steep terrain.Figure 2 Enlarged diagram of point A in the middle.
[0023] Figure 7 This invention relates to a foldable drilling equipment support suitable for steep terrain. Figure 2 Enlarged diagram of point B in the middle.
[0024] Figure 8 This invention relates to a foldable drilling equipment support suitable for steep terrain. Figure 4 Enlarged diagram of point C in the middle.
[0025] Figure 9 This invention relates to a foldable drilling equipment support suitable for steep terrain. Figure 5 Enlarged diagram of point D in the middle.
[0026] Figure 10 This invention relates to a foldable drilling equipment support suitable for steep terrain. Figure 5 Enlarged diagram of point E in the middle.
[0027] Figure 11 This invention relates to a foldable drilling equipment support suitable for steep terrain. Figure 5 Enlarged diagram of point F in the middle.
[0028] In the diagram: 1. Support body; 11. Support rod; 12. Chain drive assembly; 13. Drilling assembly; 2. Prismatic insert; 21. Clamping plate; 22. Worm gear; 23. Worm; 24. First screw; 25. First connecting pipe; 26. First slide groove; 27. First toothed plate; 28. Full toothed disc; 29. Guide block; 210. Guide groove; 211. Support plate; 2111. Slider; 2112. Second slide groove; 211 3. Second screw; 2114. First toothed block; 2115. First storage groove; 2116. Rack; 212. Connecting plate; 213. Tapered rod insert; 214. Elastic reset component; 215. Slot; 216. Half toothed disc; 217. Second toothed block; 218. Second storage groove; 219. Handwheel; 220. Tapered tooth assembly; 221. Third screw; 222. Second connecting pipe; 223. Third slide groove. Detailed Implementation
[0029] To make the objectives, technical solutions, and advantages of this invention clearer, the invention will be further described in detail below with reference to embodiments. It should be understood that the specific embodiments described herein are merely illustrative and not intended to limit the invention.
[0030] In the description of this invention, it should be understood that the terms "center," "longitudinal," "lateral," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," and "outer," etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this invention and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this invention.
[0031] Furthermore, the terms “first”, “second”, etc., are used for descriptive purposes only and should not be construed as indicating or implying relative importance or implicitly specifying the number of technical features indicated.
[0032] Therefore, features specified with "first," "second," etc., may explicitly or implicitly include one or more of that feature. In the description of this invention, unless otherwise stated, "a plurality of" means two or more.
[0033] In the description of this invention, it should be noted that, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "linking" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art will understand the specific meaning of the above terms in this invention based on the specific circumstances.
[0034] See Figure 1 and Figure 2 As shown, a foldable drilling equipment support suitable for steep terrain includes a support body 1, a support rod 11 rotatably mounted on the support body 1, a chain drive assembly 12 on one side of the support rod 11, a drilling assembly 13 mounted on the chain drive assembly 12, a ground support system for increasing the stability of the drilling assembly 13 at the sampling point on the support body 1, and a drilling angle adjustment system for adjusting the insertion angle of the drilling assembly 13 into the ground on the support body 1. The ground support system includes a prism block 2, an anti-loosening mechanism, and an anti-tilting mechanism. The prism block 2 is connected to the support body 1. The anti-loosening mechanism is mounted on the prism block 2 and is used to strengthen the fastening force between the prism block 2 and the sampling point. The anti-tilting mechanism is mounted on the support body 1 and is used to strengthen the fastening force between the support body and the sampling point.
[0035] Specifically, when installing a folding drilling equipment support on steep terrain, the support body 1 is first placed on the ground, allowing it to drive the prism block 2 into the soil to a sufficient depth. The prism block 2 increases the contact area between the support body 1 and the soil by inserting itself into the soil, thereby improving the stability of the support body 1. At this point, the anti-loosening mechanism is activated to further strengthen the fastening force between the prism block 2 and the ground, effectively preventing the support body 1 from sliding or tilting on steep or uneven terrain.
[0036] After the main support 1 is stabilized, the tilt angle of the drilling assembly 13 relative to the ground is adjusted using the drilling angle adjustment system, so that the drill bit of the drilling assembly 13 drills at a predetermined angle to adapt to different drilling needs. At the same time, by adjusting the azimuth angle of the drilling assembly 13, it is ensured that the drilling assembly 13 performs drilling operations in the correct direction.
[0037] At the same time, the staff can activate the anti-tilt mechanism to strengthen the support of the support rod 11 on the drilling component 13, ensuring that the folding drilling equipment bracket is stably placed on the ground. At this time, the staff can drive the drilling component 13 to move down to drill the ground through the chain drive component 12, avoiding the bracket from tilting or sliding due to uneven or steep ground, thereby avoiding operation failure or safety accidents caused by equipment instability.
[0038] See Figures 1 to 4 and Figure 8 As shown, the anti-loosening mechanism includes a clamping plate 21, a worm gear 22, and a worm 23; the clamping plate 21 is rotatably mounted on the prism insert 2; the worm gear 22 is rotatably mounted on the prism insert 2 and connected to the clamping plate 21; the worm 23 is rotatably mounted on the prism insert 2 and connected to the worm gear 22; the anti-loosening mechanism also includes a first screw 24, a first connecting pipe 25, and a first sliding groove 26; the first screw 24 is rotatably mounted on the prism insert 2; the first connecting pipe 25 is threadedly connected to the first screw 24; the first sliding groove 26 is open... Located on the side of the prism insert 2 near the first connecting pipe 25, the first sliding groove 26 is used to cooperate with the first connecting pipe 25 for linear movement; the first connecting pipe 25 is provided with a first toothed plate 27 and a full toothed disc 28; the upper end of the first toothed plate 27 is connected to the first connecting pipe 25, and a guide block 29 is connected to one side of the first toothed plate 27; a guide groove 210 is opened on the side of the prism insert 2 near the guide block 29, and the guide groove 210 is used to cooperate with the guide block 29 for linear movement; the full toothed disc 28 is rotatably mounted on the prism insert 2, and the full toothed disc 28 is connected to the first toothed plate 27.
[0039] Specifically, the worm gear 22 and the worm 23 form a meshing transmission pair. The first connecting pipe 25 and the first sliding groove 26 form a sliding guide pair. The first toothed plate 27 and the full toothed disc 28 form a meshing transmission pair. The guide block 29 and the guide groove 210 form a sliding guide pair.
[0040] When the support body 1 drives the prism insert 2 into the soil, the first screw 24 is rotated. Because the first connecting pipe 25 and the first sliding groove 26 form a sliding guide pair, the first connecting pipe 25 is prevented from rotating with the first screw 24. The threaded connection between the first screw 24 and the first connecting pipe 25 allows the first connecting pipe 25 to move stably upwards along the first sliding groove 26, and the first connecting pipe 25 drives the first toothed plate 27 to move upwards synchronously. When the first toothed plate 27 moves, it drives the guide block 29 to slide along the guide groove 210. The sliding guide pair between the guide block 29 and the guide groove 210 ensures the stable movement of the first toothed plate 27.
[0041] The meshing transmission pair between the first toothed plate 27 and the full toothed disc 28 drives the full toothed disc 28 to rotate, which in turn causes the full toothed disc 28 to drive the worm 23 to rotate. The meshing transmission pair between the worm wheel 22 and the worm 23 causes the worm 23 to drive the worm wheel 22 to rotate, thereby causing the clamping plate 21 to unfold from the outside of the prism block 2 to compress the soil. Utilizing the self-locking characteristics of the worm wheel 22 and the worm 23, the clamping plate 21 is not easily reset due to soil forces after unfolding. Through the compression of the soil around the prism block 2 by the clamping plate 21, the frictional resistance between the prism block 2 and the soil can be increased, reducing the relative movement between the two, preventing the support body 1 from sliding or tilting due to external forces, and avoiding loosening of the prism block 2 and the soil. This improves the stability of the support body 1, ensures the fixation of the support body 1 on steep or uneven terrain, and reduces the risk of displacement or instability during operation.
[0042] See Figure 1 , Figure 2 , Figure 5 , Figure 6 , Figure 7 and Figures 9 to 11As shown, the anti-tilt mechanism includes a support plate 211, a connecting plate 212, a tapered rod insert 213, an elastic reset member 214, and a slot 215. The support plate 211 is located on the side of the support body 1 away from the drilling assembly 13. One end of the connecting plate 212 is rotatably located at the lower end of the support plate 211. One end of the tapered rod insert 213 slidably passes through the left and right sides of the connecting plate 212. The elastic reset member 214 is sleeved with one end of the tapered rod insert 213, and both ends of the elastic reset member 214 are respectively connected to the connecting plate 212 and the tapered rod insert 213. The slot 215 is located on the side of the support body 1 near the tapered rod insert 213, and the tapered rod insert 213 is slidably located inside the slot 215. The anti-tilt mechanism also includes a slider 2111, a second slide groove 2112, and a second screw 215. 113, First toothed block 2114, First storage groove 2115, and rack 2116; Slider 2111 is rotatably mounted on support plate 211; Second slide groove 2112 is opened on the side of bracket body 1 near slider 2111, and the second slide groove 2112 is used to cooperate with slider 2111 for linear movement; Second screw 2113 is threadedly connected to slider 2111; First toothed block 2114 is rotatably mounted on second screw 2113; First storage groove 2115 is opened on the side of slider 2111 near first toothed block 2114, and first toothed block 2114 is slidably mounted in first storage groove 2115; Rack 2116 is embedded in the side of second slide groove 2112 near first toothed block 2114, and rack 2116 is connected to first toothed block 2114.
[0043] Specifically, the elastic reset element 214 uses a spring as the implementing element. The diameter of the tapered insert 213 matches the spacing between the inner walls of the slot 215. The first toothed block 2114 meshes with the rack 2116. The first receiving groove 2115 matches the first toothed block 2114. The slider 2111 and the second sliding groove 2112 form a sliding guide pair.
[0044] After the clamping plate 21 improves the stability between the prism insert 2 and the soil, the tapered insert 213 is pulled, causing the tapered insert 213 to extend the elastic reset member 214, thereby removing the tapered insert 213 from the slot 215. Then, the connecting plate 212 is rotated to disengage it from the support body 1. Next, the second screw 2113 is rotated, and the threaded connection between the second screw 2113 and the slider 2111 causes the first toothed block 2114 to move away from the rack 2116, disengaging them. At this point, the operator can pull the slider 2111 along the second slide groove 2112. The sliding guide pair between the slider 2111 and the second slide groove 2112 ensures that the slider 2111 moves without wobbling or deviation. Simultaneously, the support plate 211 is rotated, coordinating with the downward movement of the slider 2111.
[0045] When the slider 2111 moves down to the preset height, the second screw 2113 is rotated in the opposite direction, pushing the first toothed block 2114 closer to the rack 2116. Since the first receiving groove 2115 engages with the first toothed block 2114, the first toothed block 2114 can re-engage stably with the rack 2116, confining the slider 2111 within the second sliding groove 2112 and stopping its movement. Finally, the support plate 211 is rotated, causing the connecting plate 212 to approach the ground. By pressing down on the cone rod insert 213, the cone rod insert 213 is inserted into the soil, thus fixing the connecting plate 212 to the ground. The connecting plate 212, through the support plate 211, enhances the support force on the support rod 11, thereby improving the stability of the drilling assembly 13 during operation.
[0046] See Figure 1 , Figure 2 , Figure 5 and Figures 9 to 11 As shown, the drilling angle adjustment system includes a positioning mechanism and a locking mechanism. The positioning mechanism is mounted on the support body 1 and the support rod 11, and is used to limit the rotation angle of the support rod 11. The locking mechanism is mounted on the positioning mechanism and the support rod 11, and is used to prevent the support rod 11 from loosening after the angle is adjusted. The positioning mechanism includes a half-tooth disc 216, a second tooth block 217, and a second receiving groove 218. The half-tooth disc 216 is connected to the side of the support body 1 near the support rod 11. The second tooth block 217 is connected to the half-tooth disc 216. The second receiving groove 218 is opened on the side of the support rod 11 near the second tooth block 217, and is used to store the second tooth block 217 inside the support rod 11. The locking mechanism includes a handwheel 219. The support rod 11 includes a bevel gear assembly 220, a third screw 221, a second connecting pipe 222, and a third sliding groove 223. A handwheel 219 is rotatably mounted on the support rod 11. The bevel gear assembly 220 is rotatably mounted on the support rod 11, with its rotating end connected to the end of the handwheel 219. The third screw 221 is rotatably mounted on the support rod 11, and its rotating end away from the handwheel 219 is connected to the bevel gear assembly 220. The second connecting pipe 222 is slidably mounted on the support rod 11 and is threadedly connected to the third screw 221. The third sliding groove 223 is located on the side of the support rod 11 near the second connecting pipe 222, and is used to cooperate with the second connecting pipe 222 for linear movement.
[0047] Specifically, the half-tooth disc 216 meshes with the second tooth block 217. The second tooth block 217 matches the second receiving groove 218. The bevel gear assembly 220 consists of two meshing bevel gears. The second connecting pipe 222 matches the third sliding groove 223, and the cross-sectional shape of the second connecting pipe 222 is rectangular, which enables sliding guidance.
[0048] After the clamping plate 21 completes the compression of the soil outside the prism insert 2, before the anti-tilting mechanism is activated, the bevel gear of the bevel gear assembly 220 is driven to rotate by the handwheel 219. Utilizing the meshing transmission of the bevel gear assembly 220, the handwheel 219 drives the third screw 221 to rotate. Due to the rectangular cross-section fit structure between the second connecting pipe 222 and the third sliding groove 223, the third sliding groove 223 can restrict the second connecting pipe 222 from rotating with the third screw 221. Through the threaded connection between the third screw 221 and the second connecting pipe 222, the second connecting pipe 222 moves stably upward along the third sliding groove 223, driving the second toothed block 217 into the second receiving groove 218, thus disengaging the second toothed block 217 from the half-toothed disc 216.
[0049] At this point, the support rod 11 can be rotated, and the ground tilt angle of the drilling assembly 13 can be adjusted via the chain drive assembly 12. After the angle of the drilling assembly 13 is adjusted, the handwheel 219 is rotated in the opposite direction, causing the second connecting pipe 222 to drive the second toothed block 217 to re-engage with the half-toothed disc 216, locking the rotation angle of the support rod 11, ensuring that the drilling assembly 13 drills at a predetermined angle to adapt to different drilling needs and ensure the accuracy of the drilling direction.
[0050] Working Principle: When the folding drilling equipment support is put into use, the support body 1 drives the prism block 2 to insert into the soil. Rotating the first screw 24 causes the clamping plate 21 to unfold from the outside of the prism block 2, compressing the soil and improving the stability of the support body 1. Then, rotating the handwheel 219 disengages the second toothed block 217 from the half-toothed disc 216. Next, rotating the support rod 11 adjusts the ground tilt angle of the drilling assembly 13, and then locking the rotation angle of the support rod 11. Finally, pulling the tapered rod block 213 disengages the connecting plate 212 from the support body 1. Then, rotating the second screw 2113 causes the slider 2111 to move downwards while the support plate 211 rotates, fixing the connecting plate 212 to the ground. The connecting plate 212, through the support plate 211, enhances the support force on the support rod 11, thereby improving the stability of the drilling assembly 13 during operation.
[0051] The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention. Any modifications, equivalent substitutions, and improvements made within the spirit and principles of the present invention should be included within the protection scope of the present invention.
Claims
1. A folding drilling equipment support suitable for steep terrain, comprising a support body (1), a support rod (11) rotatably mounted on the support body (1), a chain drive assembly (12) on one side of the support rod (11), and a drilling assembly (13) mounted on the chain drive assembly (12), characterized in that, The main body of the support (1) is equipped with a ground support system to increase the stability of the drilling assembly (13) at the sampling point; The main body of the support (1) is equipped with a drilling angle adjustment system for adjusting the angle at which the drilling assembly (13) is inserted into the ground.
2. The folding drilling equipment support suitable for steep terrain according to claim 1, characterized in that, The ground support system includes a prism insert (2), an anti-loosening mechanism, and an anti-tilting mechanism; The prism insert (2) is connected to the support body (1); The anti-loosening mechanism is set on the prism insert (2) and is used to strengthen the fastening force between the prism insert (2) and the sampling point; The anti-tilting mechanism is installed on the support body (1) and is used to strengthen the fastening force between the support body (1) and the sampling point.
3. The folding drilling equipment support suitable for steep terrain according to claim 2, characterized in that, The anti-loosening mechanism includes a clamping plate (21), a worm gear (22), and a worm (23); The card plate (21) is rotatably mounted on the prism insert (2); The worm gear (22) is rotatably mounted on the prism insert (2), and the worm gear (22) is connected to the clamping plate (21); The worm (23) is rotatably mounted on the prism insert (2), and the worm (23) is connected to the worm wheel (22).
4. The folding drilling equipment support suitable for steep terrain according to claim 3, characterized in that, The anti-loosening mechanism also includes a first screw (24), a first connecting pipe (25), and a first sliding groove (26); The first screw (24) is rotatably mounted on the prism insert (2); The first connecting pipe (25) is threadedly connected to the first screw (24); The first groove (26) is opened on the side of the prism insert (2) near the first connecting tube (25), and the first groove (26) is used to cooperate with the first connecting tube (25) to move linearly.
5. The folding drilling equipment support for steep terrain according to claim 4, characterized in that, The first connecting pipe (25) is provided with a first toothed plate (27) and a full toothed disc (28); The upper end of the first toothed plate (27) is connected to the first connecting pipe (25). A guide block (29) is connected to one side of the first toothed plate (27). A guide groove (210) is provided on the side of the prism insert (2) near the guide block (29). The guide groove (210) is used to cooperate with the guide block (29) to move linearly. The full toothed disc (28) is rotatably mounted on the prism insert (2), and the full toothed disc (28) is connected to the first toothed plate (27).
6. The folding drilling equipment support suitable for steep terrain according to claim 2, characterized in that, The anti-tilt mechanism includes a support plate (211), a connecting plate (212), a cone rod insert (213), an elastic reset member (214), and a slot (215). The support plate (211) is located on the side of the support body (1) away from the drilling assembly (13); One end of the connecting plate (212) is rotatably disposed at the lower end of the support plate (211); One end of the tapered rod insert (213) can slide through the left and right sides of the connecting plate (212); The elastic reset component (214) is sleeved on one end of the tapered rod insert (213), and the two ends of the elastic reset component (214) are respectively connected to the connecting plate (212) and the tapered rod insert (213); The slot (215) is located on the side of the support body (1) near the tapered rod insert (213), and the tapered rod insert (213) is slidably disposed inside the slot (215).
7. The folding drilling equipment support suitable for steep terrain according to claim 6, characterized in that, The anti-tilt mechanism also includes a slider (2111), a second slide groove (2112), a second screw (2113), a first toothed block (2114), a first storage groove (2115), and a rack (2116). The slider (2111) is rotatably mounted on the support plate (211); The second slide (2112) is provided on the side of the support body (1) near the slider (2111). The second slide (2112) is used to cooperate with the slider (2111) to move linearly. The second screw (2113) is threadedly connected to the slider (2111); The first toothed block (2114) is rotatably mounted on the second screw (2113); The first storage slot (2115) is opened on the side of the slider (2111) near the first toothed block (2114), and the first toothed block (2114) is slidably disposed in the first storage slot (2115); The rack (2116) is embedded in the second groove (2112) on the side near the first tooth block (2114), and the rack (2116) is connected to the first tooth block (2114).
8. The folding drilling equipment support suitable for steep terrain according to claim 1, characterized in that, The drilling angle adjustment system includes a positioning mechanism and a locking mechanism; The positioning mechanism is set on the support body (1) and the support rod (11). The positioning mechanism is used to limit the rotation angle of the support rod (11). The locking mechanism is installed on the positioning mechanism and the support rod (11). The locking mechanism is used to prevent the support rod (11) from loosening after the angle is adjusted.
9. The folding drilling equipment support suitable for steep terrain according to claim 8, characterized in that, The positioning mechanism includes a half-tooth disc (216), a second tooth block (217), and a second storage groove (218). The half-tooth disc (216) is connected to the side of the support body (1) near the support rod (11); The second tooth block (217) mates with the half tooth disk (216); The second storage slot (218) is provided on the side of the support rod (11) near the second tooth block (217), and the second storage slot (218) is used to store the second tooth block (217) inside the support rod (11).
10. The folding drilling equipment support for steep terrain according to claim 8, characterized in that, The locking mechanism includes a handwheel (219), a bevel gear assembly (220), a third screw (221), a second connecting pipe (222), and a third slide groove (223). The handwheel (219) is rotatably mounted on the support rod (11); The bevel gear assembly (220) is rotatably mounted on the support rod (11), and the rotating end of the bevel gear assembly (220) is connected to the end of the handwheel (219); The third screw (221) is rotatably mounted on the support rod (11), and the third screw (221) is connected to the rotating end of the bevel gear assembly (220) away from the handwheel (219); The second connecting pipe (222) is slidably mounted on the support rod (11), and the second connecting pipe (222) is threadedly connected to the third screw (221); The third slide (223) is located on the side of the support rod (11) near the second connecting pipe (222). The third slide (223) is used to cooperate with the second connecting pipe (222) for linear movement.