CN213780372U - Be used for mine geological environment monitoring devices - Google Patents

Abstract

The utility model discloses a be used for mine geological environment monitoring devices relates to geological environment and detects technical field, which comprises a vehicle rack, the below fixedly connected with telescopic link of frame, and the outside of telescopic link has cup jointed first spring, the bottom fixed mounting of first spring has the mount, and the inside of mount is provided with first gear piece, first gear piece outside fixedly connected with gear post, and the opposite side fixed mounting of gear post has second gear piece, the bottom welding of gear post has the supporting shoe. The utility model discloses in, start driving motor, servo motor, driving motor makes the drill bit carry out the operation of going up and down, and servo motor drives the drill bit through bearing, column spinner and carries out the rotation operation, just puts the soil moisture monitoring work of accomplishing the ore deposit soil through the lifting and falling rotation of drill bit, and this monitoring mechanism operates steadily, convenient to use, and has reduced staff's work load, has shortened measuring time, has improved measurement of efficiency.

Description

Be used for mine geological environment monitoring devices

Technical Field

The utility model relates to a geological environment detects technical field, especially relates to a be used for mine geological environment monitoring devices.

Background

With the development of science and technology and the progress of times, the mining industry in China is rapidly developed, the mining industry provides important substance guarantee for the development of economic society and simultaneously accumulates a large number of geological environment problems, aiming at the problems, the national resource ministry sets mine geological environment protection regulations, and the problems of mining collapse, underground water drainage, geological landscape damage and the like caused by mining activities in China seriously jeopardize the normal production and life of people in mining areas and restrict the sustainable development of local economic society.

The prior art has the following problems: 1. when the existing geological environment monitoring device is used for measuring the moisture content in the deep soil of a mine, the deep soil is mostly excavated manually and then is measured, the process is time-consuming and labor-consuming, and the measuring efficiency is low; 2. the existing geological environment monitoring device is extremely complex in the monitoring process, the road surface is bumpy and the uphill and downhill slopes are more, so that the existing geological environment monitoring device is extremely easy to damage and inconvenient to use, and the detection effect on a geological environment monitoring target is seriously influenced.

SUMMERY OF THE UTILITY MODEL

To solve the problems set forth in the background art described above. The utility model provides a be used for mine geological environment monitoring devices.

In order to achieve the above object, the utility model provides a following technical scheme:

a device for monitoring mine geological environment comprises a frame, wherein a telescopic rod is fixedly connected below the frame, a first spring is sleeved outside the telescopic rod, a fixed frame is fixedly installed at the bottom of the first spring, a first gear block is arranged inside the fixed frame, a gear column is fixedly connected to the outer side of the first gear block, a second gear block is fixedly installed at the other side of the gear column, supporting blocks are welded at the bottom of the gear column, universal wheels are arranged between the supporting blocks in an opposite mode, a supporting frame is fixedly installed at the top of the frame, a driving motor is arranged inside the supporting frame, a driving gear block is sleeved outside the driving motor, a driven gear block is fixedly installed on the left side of the driving gear block, a threaded column is sleeved inside the driven gear block, a rotating block is sleeved outside the threaded column, a servo motor is fixedly installed on the left side of the rotating block, and servo motor's outside has cup jointed the bearing, the other end of bearing is inside to have cup jointed the column spinner, and the inside fixed mounting of column spinner has soil moisture monitor, the inside fixed mounting of column spinner has the second spring, and opposite face welding between the second spring has a fixed column, the outside of fixed column runs through there is the fixed column, and the outside movable mounting of fixed column has solid fixed ring, the front welding of fixed column has the fixed block, the bottom welding of fixed column has the drill bit.

Preferably, a rubber pad is fixedly mounted at the top of the frame, and a ground penetrating radar is fixedly mounted at the top of the rubber pad.

Preferably, the supporting block forms a lifting structure through the first gear block, the second gear block, the gear column and the fixing frame, and the first gear block is meshed with the second gear block through the gear column.

Preferably, the drill bit forms a rotating structure through the servo motor, the bearing, the rotating column and the support frame, and the inner wall of the bearing is tightly connected with the servo motor.

Preferably, the limiting column forms a moving structure through the second spring, the fixing block and the fixing column, and the outer wall of the limiting column is tightly attached to the inner wall of the fixing column when meeting.

Preferably, the drill bit forms a lifting structure through the driving motor, the driven gear block, the rotating block and the frame, and the rotating block is internally in a thread structure.

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

1. the utility model discloses in, start driving motor, servo motor, driving motor makes the drill bit carry out the operation of going up and down, and servo motor drives the drill bit through bearing, column spinner and carries out the rotation operation, just puts the soil moisture monitoring work of accomplishing the ore deposit soil through the lifting and falling rotation of drill bit, and this monitoring mechanism operates steadily, convenient to use, and has reduced staff's work load, has shortened measuring time, has improved measurement of efficiency.

2. The utility model discloses in, the manual operation fixed block, the fixed block passes through the second spring and drives the restriction post and remove the operation, just so conveniently change the drill bit, when changing the completion, loosen the fixed block, the restriction post carries out the work of resetting through the second spring, just so accomplished the change work of drill bit, this change mechanism, moreover, the steam generator is simple in structure, high durability and convenient use, and shortened the change time of drill bit, the measurement of efficiency is improved, the manual operation rotation handle, the rotation handle is through first gear piece, the second gear piece, the gear post drives the supporting shoe and carries out the operation of going up and down, just so conveniently accomplish the fixed work of frame, this fixed establishment conveniently carries out fixed work in different rugged and rugged highway sections, thus, the work efficiency is just improved.

3. The utility model discloses in, when the frame removes to the highway section of jolting for the telescopic link carries out flexible operation through first spring, just carries out buffering work to ground penetrating radar through telescopic link, block rubber, first spring, just so protects work to ground penetrating radar, has prolonged ground penetrating radar oil life, the effectual work efficiency that has improved.

Drawings

FIG. 1 is a schematic structural view of a geological environment monitoring device of the present invention;

FIG. 2 is an enlarged schematic view of the structure at A in FIG. 1;

fig. 3 is a schematic view of the connection structure of the middle rotary column and the drill bit of the present invention.

In the figure: 1. a frame; 2. a rubber pad; 3. a ground penetrating radar; 4. a support frame; 5. a telescopic rod; 6. a first spring; 7. a fixed mount; 8. a universal wheel; 9. a support block; 10. a gear post; 11. a drive motor; 12. driving the gear block; 13. a driven gear block; 14. a threaded post; 15. rotating the block; 16. a servo motor; 17. a bearing; 18. a spin column; 19. a soil moisture monitor; 20. a drill bit; 21. a first gear block; 22. a second gear block; 23. a second spring; 24. defining a column; 25. a fixed block; 26. a fixing ring; 27. and (5) fixing the column.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides the following technical solutions:

a device for monitoring mine geological environment comprises a frame 1, arubber pad 2, aground penetrating radar 3, asupport frame 4, atelescopic rod 5, afirst spring 6, afixed frame 7, auniversal wheel 8, asupport block 9, agear column 10, adriving motor 11, adriving gear block 12, a drivengear block 13, a threadedcolumn 14, a rotatingblock 15, aservo motor 16, abearing 17, a rotatingcolumn 18, asoil moisture monitor 19, adrill bit 20, afirst gear block 21, asecond gear block 22, asecond spring 23, alimiting column 24, afixed block 25, afixed ring 26 and afixed column 27, wherein thetelescopic rod 5 is fixedly connected to the lower part of the frame 1, thefirst spring 6 is sleeved on the outer part of thetelescopic rod 5, thefixed frame 7 is fixedly installed at the bottom of thefirst spring 6, thefirst gear block 21 is arranged inside thefixed frame 7, thegear column 10 is fixedly connected to the outer side of thefirst gear block 21, thesecond gear block 22 is fixedly installed on the other side of thegear column 10, the bottom of thegear column 10 is welded with a supportingblock 9,universal wheels 8 are arranged on opposite surfaces between the supportingblocks 9, a supportingframe 4 is fixedly installed at the top of the frame 1, a drivingmotor 11 is arranged inside the supportingframe 4, adriving gear block 12 is sleeved outside thedriving motor 11, a drivengear block 13 is fixedly installed on the left side of thedriving gear block 12, a threadedcolumn 14 is sleeved inside the drivengear block 13, a rotatingblock 15 is sleeved outside the threadedcolumn 14, aservo motor 16 is fixedly installed on the left side of the rotatingblock 15, abearing 17 is sleeved outside theservo motor 16, a rotatingcolumn 18 is sleeved inside the other end of thebearing 17, asoil moisture monitor 19 is fixedly installed inside therotating column 18, asecond spring 23 is fixedly installed inside therotating column 18, alimiting column 24 is welded on the opposite surface between thesecond springs 23, and afixing column 27 penetrates through the outside thelimiting column 24, and the outside offixed column 27 is movably installed withfixed ring 26, the front of limitingcolumn 24 is welded withfixed block 25, and the bottom of fixedcolumn 27 is welded withdrill bit 20.

As shown in fig. 1, arubber pad 2 is fixedly installed on the top of a vehicle frame 1, aground penetrating radar 3 is fixedly installed on the top of therubber pad 2, and when the monitoring device runs on a bumpy road section, theground penetrating radar 3 performs buffering work through therubber pad 2.

As shown in fig. 1 and 2, the supportingblock 9 forms a lifting structure with thefixed frame 7 through thefirst gear block 21, thesecond gear block 22, thegear column 10, and thefirst gear block 21 is engaged with thesecond gear block 22 through thegear column 10, the rotating handle is manually operated, and the rotating handle drives the supportingblock 9 to lift through thefirst gear block 21, thesecond gear block 22 and thegear column 10, so as to conveniently complete the fixing work of the frame 1.

As shown in fig. 1, thedrill bit 20 forms a rotating structure with thesupport frame 4 through theservo motor 16, thebearing 17, therotary column 18, and the inner wall of thebearing 17 is tightly connected with theservo motor 16, theservo motor 16 is started, and theservo motor 16 drives thedrill bit 20 to rotate through thebearing 17 and therotary column 18, so that the moisture monitoring work of the ore soil is conveniently completed.

As shown in fig. 3, the limitingcolumn 24 forms a moving structure through thesecond spring 23, the fixingblock 25 and the fixingcolumn 27, the outer wall of the limitingcolumn 24 is tightly attached to the inner wall of the fixingcolumn 27, the fixingblock 25 is manually operated, and the fixingblock 25 drives the limitingcolumn 24 to move through thesecond spring 23, so that the replacement work of thedrill bit 20 is conveniently completed.

As shown in fig. 1, thedrill bit 20 forms a lifting structure with the frame 1 through the drivingmotor 11, the drivengear block 13, the rotatingblock 15, and the inside of therotating block 15 is in a thread structure, the drivingmotor 11 is started, and the drivingmotor 11 drives thedrill bit 20 to lift through the drivengear block 13 and therotating block 15, so that the moisture monitoring work of the ore soil is conveniently completed.

The utility model discloses a theory of operation and use flow: when the device is used, firstly, the universal wheel 8 drives the frame 1 to move, when the device moves to a bumpy road section, the telescopic rod 5 drives the first spring 6 to compress, so that the ground penetrating radar 3 is buffered (the ground penetrating radar 3 is buffered through the rubber pad 2), when the frame 1 moves to a specified position, the rotary handle is manually operated, the rotary handle drives the first gear block 21 to rotate, the first gear block 21 drives the gear post 10 to lift through the second gear block 22, the gear post 10 drives the supporting block 9 to lift, so that the fixed work of the frame 1 is conveniently completed, the driving motor 11 (model: YS7124) and the servo motor 16 (model: JX5622) are started, the driving motor 11 drives the driving gear block 12 to rotate, the driving gear block 12 drives the driven gear block 13 to rotate, the driven gear block 13 drives the threaded post 14 to rotate, the rotation of the threaded column 14 enables the rotary block 15 to carry out lifting operation, the rotary block 15 drives the drill bit 20 to carry out lifting operation through the servo motor 16, the bearing 17 and the rotary column 18, the servo motor 16 drives the rotary column 18 to carry out rotating operation through the bearing 17, the rotary column 18 drives the drill bit 20 to carry out rotating operation, thus the moisture monitoring work of the ore soil (the monitoring work is carried out through the soil moisture monitor 19 in the rotary column 18) is conveniently finished, when the drill bit 20 needs to be replaced, the fixing block 25 is manually operated, the fixing block 25 drives the limiting column 24 to carry out moving operation, the limiting column 24 drives the second spring 23 to carry out compressing operation, then the drill bit 20 is operated, the fixing column 27 is moved out of the fixing ring 26 by the drill bit 20, thus the replacing work of the drill bit 20 is conveniently finished, when the replacing operation of the drill bit 20 is finished, the fixing block 25 is loosened, the fixing block 25 enables the limiting column 24 to carry out resetting work through the second spring 23, the limiting post 24 will pass through the fixing post 27, thus completing the installation of the drill bit 20.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a be used for mine geological environment monitoring devices, includes frame (1), its characterized in that: the lower part of the frame (1) is fixedly connected with a telescopic rod (5), a first spring (6) is sleeved outside the telescopic rod (5), a fixing frame (7) is fixedly installed at the bottom of the first spring (6), a first gear block (21) is arranged inside the fixing frame (7), a gear column (10) is fixedly connected to the outer side of the first gear block (21), a second gear block (22) is fixedly installed on the other side of the gear column (10), supporting blocks (9) are welded at the bottom of the gear column (10), universal wheels (8) are arranged between the supporting blocks (9) in a way of opposite faces, a supporting frame (4) is fixedly installed at the top of the frame (1), a driving motor (11) is arranged inside the supporting frame (4), a driving gear block (12) is sleeved outside the driving motor (11), and a driven gear block (13) is fixedly installed on the left side of the driving gear block (12), a threaded column (14) is sleeved inside the driven gear block (13), a rotating block (15) is sleeved outside the threaded column (14), a servo motor (16) is fixedly installed on the left side of the rotating block (15), a bearing (17) is sleeved outside the servo motor (16), a rotating column (18) is sleeved inside the other end of the bearing (17), and a soil moisture monitor (19) is fixedly arranged inside the rotating column (18), a second spring (23) is fixedly arranged in the rotating column (18), a limiting column (24) is welded on the opposite surface between the second springs (23), a fixing column (27) penetrates through the outside of the limiting column (24), and the outside movable mounting of fixed column (27) has solid fixed ring (26), the front welding of restriction post (24) has fixed block (25), the bottom welding of fixed column (27) has drill bit (20).

2. The mine geological environment monitoring device according to claim 1, characterized in that: the ground penetrating radar is characterized in that a rubber pad (2) is fixedly mounted at the top of the frame (1), and a ground penetrating radar (3) is fixedly mounted at the top of the rubber pad (2).

3. The mine geological environment monitoring device according to claim 1, characterized in that: the supporting block (9) forms a lifting structure with the fixing frame (7) through the first gear block (21), the second gear block (22), the gear column (10), and the first gear block (21) is meshed with the second gear block (22) through the gear column (10).

4. The mine geological environment monitoring device according to claim 1, characterized in that: the drill bit (20) forms a rotating structure with the support frame (4) through the servo motor (16), the bearing (17), the rotating column (18), and the inner wall of the bearing (17) is tightly connected with the servo motor (16).

5. The mine geological environment monitoring device according to claim 1, characterized in that: the limiting column (24) forms a moving structure through the second spring (23), the fixing block (25) and the fixing column (27), and the outer wall of the limiting column (24) is tightly attached to the inner wall of the fixing column (27).

6. The mine geological environment monitoring device according to claim 1, characterized in that: the drill bit (20) forms a lifting structure with the frame (1) through the driving motor (11), the driven gear block (13), the rotating block (15), and the inside of the rotating block (15) is in a thread structure.

Images