CN115075724A - High-stability drilling equipment for water disaster emission in coal mining area - Google Patents

Abstract

The invention relates to the technical field of drilling equipment, in particular to high-stability drilling equipment for water disaster emission in coal mining areas, which comprises a drill rod, a drill bit and a quick-connecting piece, wherein a plurality of tooth sockets are formed in the outer wall of the drill rod, the drill bit is arranged at the head of the drill rod, the quick-connecting piece is arranged at the tail of the drill rod, a plurality of cambered plates are arranged around the drill rod, two extrusion wheels are rotationally arranged in the cambered plates, and teeth are arranged on the circumferential outer walls of the extrusion wheels; through the structure that adopts drilling rod, bow-shaped board and extrusion wheel to carry out drilling work, can reduce the drilling rod and creep into the influence of vibration phenomenon to conveyor motor, the propulsive force of the rotation moment of torsion conversion of conveyor motor into the drilling rod is conveniently simultaneously, improve equipment life to a plurality of drilling rod lug connections advance work through the extrusion wheel, can effectively shorten the middle transition time of equipment during operation, improve drilling speed greatly, improve work efficiency.

Description

High-stability drilling equipment for water disaster emission in coal mining area

Technical Field

The invention relates to the technical field of drilling equipment, in particular to high-stability drilling equipment for water disaster emission in a coal mining area.

Background

As is well known, in the process of mining operation in a mining area, water in underground cracks and rock stratums needs to be pumped away, and underground water drainage is achieved, so that the water damage hazard of coal mining is reduced, the harm of underground water to workers in underground mining operation is avoided, the risk that water flow drives the rock stratums to loosen and cause mine caves to sink is reduced, and the water damage drainage operation mainly comprises the step of arranging drainage holes in a mining area, so that underground water is naturally discharged under pressure or water is pumped out through pump equipment.

The drilling machine is a necessary device for arranging the dredging holes, the traditional drilling machine drives the drill rod and the drill bit to rotate through the motor when in use, the motor is pushed to move through the hydraulic device, so that the drill rod and the drill bit are pushed to drill underground and realize drilling work, after the drill rod extends into the underground, the motor is closed and is separated from the drill rod, then the motor is moved to the initial position, the next drill rod is fixed on the motor and the initial drill rod, the motor is started and is pushed to move, the drilling work of the drill rod is realized, repeated operation is carried out, and the continuous drilling work of the drilling machine is realized, however, when the drilling machine is adopted, the drill rod is directly connected with the motor, the drill rod is easy to vibrate violently when in the drilling work, the drill rod transmits the vibration into the motor, the rotor in the motor is easy to vibrate and damage, the service life of the motor is influenced, and the hydraulic device transmits the propelling force to the drill rod through the motor, the motor is subjected to large axial force, generally, the motor mainly achieves the purpose of transmitting torque and rotating speed, the motor is poor in the aspect of transmitting the axial force, the motor is easily damaged, the service life of equipment is influenced, the speed for pushing the motor to reciprocate and repeatedly push drilling is low, and the working efficiency is low.

Disclosure of Invention

In order to solve the technical problem, the invention provides high-stability drilling equipment for water disaster emission in a coal mining area.

In order to achieve the purpose, the invention adopts the technical scheme that:

coal mining area water damage discharges and uses high stable drilling equipment, including the drilling rod, drill bit and fast union piece, a plurality of tooth's sockets have been seted up on the outer wall of drilling rod, the head at the drilling rod is installed to the drill bit, the afterbody at the drilling rod is installed to the fast union piece, be provided with a plurality of bows board around the direction all around of drilling rod, the bows inboard internal rotation is provided with two extrusion wheels, be provided with the tooth on the extrusion wheel circumference outer wall, tooth meshing on the tooth on the extrusion wheel and the drilling rod, be provided with conveying motor on the outer wall of one of them bows board, conveying motor is connected rather than an extrusion wheel transmission in the last bows board.

Further, establish the rotary drum in the drilling rod outside including the cover, be provided with a plurality of guide rails and two support rings on the rotary drum inner wall, the slope rotates on the support ring inner wall and is provided with multiunit ejector plate, and every group ejector plate comprises two ejector plates, and the outer end of ejector plate is rotated and is installed on the outer wall of bow-shaped board.

Further, still include the external fixation section of thick bamboo, the drilling rod passes the external fixation section of thick bamboo and removes, and the rotary drum rotates to be installed on the external fixation section of thick bamboo inner wall, installs a plurality of first cylinders on the rotary drum inner wall, and the expansion end of first cylinder is connected with the support ring on the guide rail, and rotating electrical machines is installed at the external fixation section of thick bamboo top, and rotating electrical machines's output is provided with first gear, is provided with the tooth on the circumference inner wall of rotary drum, and first gear is connected with the tooth meshing on the rotary drum.

Further, still including carrying a section of thick bamboo, carrying a section of thick bamboo to be located the afterbody side of drilling rod, carrying a both ends of section of thick bamboo and all rotating and installing the swivel becket, installing a plurality of second cylinders on the swivel becket inner wall, splint are installed to the expansion end of second cylinder, carry and install a plurality of third cylinders on the section of thick bamboo outer wall, the stiff end of third cylinder is installed on external fixation section of thick bamboo outer wall.

Furthermore, a first telescopic rod is arranged between two adjacent second cylinders in the rotating ring, a corner guide plate is fixed at the movable end of the first telescopic rod, and two ends of the corner guide plate are respectively inserted into two adjacent clamping plates in a sliding manner.

Furthermore, a synchronous motor and a double-output-shaft speed reducer are mounted on the outer wall of the conveying cylinder, the synchronous motor is in transmission connection with the double-output-shaft speed reducer, rotating shafts are fixed to two output ends of the double-output-shaft speed reducer, a second gear is fixed to the outer end of each rotating shaft, teeth are arranged on the circumferential outer wall of the rotating ring, and the second gear is in meshed connection with the teeth on the rotating ring.

Further, a clamping cylinder is installed in the tip rotation of outer fixed cylinder towards the drill bit, be fixed with a plurality of second telescopic links on the clamping cylinder inner wall, the radial direction of a clamping cylinder is followed to the second telescopic link, the expansion end of second telescopic link is fixed with the bow-shaped frame, the leading wheel is installed to the bow-shaped frame internal rotation, the leading wheel is with the outer wall extrusion contact of drilling rod, it is provided with the shift ring to slide in the clamping cylinder, be provided with a plurality of roof pressure boards and a plurality of leaf spring on the shift ring inner wall, the roof pressure board rotates with the shift ring to be connected, the roof pressure board slope, the outer end of roof pressure board rotates and installs on the bow-shaped frame, the outer end of leaf spring is fixed on clamping cylinder inner wall.

Further, annular storehouse is installed towards one side of drill bit to outer fixed cylinder inner wall, and the slope intercommunication is provided with a plurality of spray tubes on the annular storehouse inner wall, and the spray tube slope is fixed with the inlet tube on the outer fixed cylinder outer wall towards the drill bit direction, inlet tube and annular storehouse intercommunication.

Compared with the prior art, the invention has the beneficial effects that: through adopting the drilling rod, the structure of bow-shaped board and extrusion wheel carries out drilling work, can realize the separation drive mode of conveyor motor and drilling rod, reduce the drilling rod and creep into the influence of vibration phenomenon to conveyor motor, avoid the violent vibration of rotor in the conveyor motor and lead to damaging, the convenient propulsive force that converts conveyor motor's rotation torque into the drilling rod that will carry simultaneously, the convenience is protected conveyor motor, avoid conveyor motor to bear the axial force and lead to damaging, improve equipment life, and a plurality of drilling rod lug connection carry out propulsive work through the extrusion wheel, the middle transition time when can effectively shorten equipment operation, equipment only need dock two drilling rods and can continue to creep into work, improve drilling speed greatly, and the work efficiency is improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments described in the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic sectional view of the outer fixed cylinder of FIG. 1;

FIG. 3 is an enlarged view of the drill stem of FIG. 2;

FIG. 4 is an enlarged top view of the swivel ring of FIG. 1;

FIG. 5 is an enlarged top view of the clamping cylinder of FIG. 2;

in the drawings, the reference numbers: 1. a drill stem; 2. a drill bit; 3. a quick connection part; 4. an arcuate plate; 5. an extrusion wheel; 6. a conveying motor; 7. a rotating drum; 8. a guide rail; 9. a support ring; 10. pushing the plate; 11. an outer fixed cylinder; 12. a first cylinder; 13. a rotating electric machine; 14. a first gear; 15. a delivery cylinder; 16. a rotating ring; 17. a second cylinder; 18. a splint; 19. a third cylinder; 20. a first telescopic rod; 21. a corner guide plate; 22. a synchronous motor; 23. a speed reducer with double output shafts; 24. a rotating shaft; 25. a second gear; 26. a clamping cylinder; 27. a second telescopic rod; 28. an arched frame; 29. a guide wheel; 30. a moving ring; 31. a top pressing plate; 32. a plate spring; 33. an annular bin; 34. a nozzle; 35. and (4) a water inlet pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it should be noted that the directions or positional relationships indicated by "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like are based on the directions or positional relationships shown in the drawings, and are only for convenience of description and simplification of the description, but do not indicate or imply that the device or element referred to must have a specific direction, be constructed and operated in a specific direction, and thus, should not be construed as limiting the present invention.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; either directly or indirectly through intervening media, or may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in a specific case to those of ordinary skill in the art. This embodiment is written in a progressive manner.

As shown in figure 3, the high-stability drilling device for water damage emission in the coal mining area comprises a drill rod 1, a drill bit 2 and a quick-connecting piece 3, wherein a plurality of tooth sockets are formed in the outer wall of the drill rod 1, the drill bit 2 is installed at the head of the drill rod 1, the quick-connecting piece 3 is installed at the tail of the drill rod 1, a plurality of cambered plates 4 are arranged around the drill rod 1, two extrusion wheels 5 are rotatably arranged in the cambered plates 4, teeth are arranged on the circumferential outer walls of the extrusion wheels 5, the teeth on the extrusion wheels 5 are meshed with the teeth on the drill rod 1, a conveying motor 6 is arranged on the outer wall of one cambered plate 4, and the conveying motor 6 is in transmission connection with one extrusion wheel 5 in the upper cambered plate 4.

Specifically, the cross-sectional shape of the drill rod 1 is square, the number of tooth sockets on the drill rod 1 is four, and the four tooth sockets are respectively positioned on four surfaces of the drill rod 1, the tooth socket direction is along the length direction of the drill rod 1, the drilling area can be drilled through the drill bit 2, the two drill rods 1 can be in butt joint connection through the quick connector 3, the number of the segmental plates 4 is four, the position of each segmental plate 4 corresponds to one edge on the drill rod 1, the teeth on the extrusion wheels 5 are positioned in the middle of the circumferential outer wall of the extrusion wheel 5, the rest positions of the circumferential outer wall of the extrusion wheel 5 are smooth surfaces, the outer wall of the extrusion wheel 5 is in contact with the outer wall of the drill rod 1, the drill rod 1 can be pushed to move up and down by rotating the extrusion wheel 5, meanwhile, the two extrusion wheels 5 are arranged in each segmental plate 4, the outer wall of the drill rod 1 can be conveniently extruded and fixed through the two extrusion wheels 5, thereby guarantee drilling rod 1 steady removal to the convenience leads the processing to drilling rod 1, through the circumference outer wall smooth surface that makes extrusion wheel 5 and the contact of drilling rod 1 outer wall, can realize extrusion wheel 5 to the extrusion fixed work of drilling rod 1, take place to rock when avoiding drilling rod 1 to remove, stability when improving drilling rod 1 and remove, four bow-shaped boards 4 are synchronous to four faces of drilling rod 1 and are extruded fixedly, thereby realize drilling rod 1's all-round fixed work.

In the embodiment, the conveying motor 6 drives the extrusion wheel 5 in the upper cambered plate 4 to rotate, so as to drive the drill rod 1 to move, the drill rod 1 drives the rest extrusion wheels 5 to synchronously rotate, so as to realize the extrusion fixing, positioning and conveying of the extrusion wheels 5 to the drill rod 1, and ensure the smooth movement of the drill rod 1, the drill rod 1 drives the drill bit 2 to move, the cambered plates 4 rotate around the axis of the drill rod 1, so as to drive the drill rod 1 to rotate, so as to realize the purpose of rotary feeding of the drill rod 1, the drill rod 1 drives the drill bit 2 to synchronously operate, the drill bit 2 rotates and drills into the ground, so as to realize the drilling operation, at the moment, the height positions of the cambered plates 4 are kept fixed, the next drill rod 1 is butted on the upper drill rod 1 through the quick connector 3, the extrusion wheels 5 on the cambered plates 4 continuously convey the drill rod 1 which is butted, so as to realize the continuous drilling operation, the working efficiency is improved.

It can be seen that, through adopting drilling rod 1, the structure of bow-shaped board 4 and extrusion wheel 5 carries out drilling work, can realize the separation drive mode of conveyor motor 6 and drilling rod 1, reduce the influence of drilling rod 1 and creep into vibration phenomenon to conveyor motor 6, avoid the interior rotor of conveyor motor 6 to acutely vibrate and lead to damaging, the rotation torque who conveniently will convey motor 6 simultaneously converts the propulsive force of drilling rod 1 into, conveniently protect conveyor motor 6, avoid conveyor motor 6 to bear the axial force and lead to damaging, improve equipment life, and a plurality of drilling rod 1 lug connection advance work through extrusion wheel 5, can effectively shorten the middle transition time when equipment moves, equipment only need to dock two drilling rod 1 and can continue to creep into work, improve drilling rate greatly, improve work efficiency.

In practical use, the pushing and clamping work of the drill rod 1 is realized by adopting the structures of the arched plates 4 and the extrusion wheels 5, the structural mode is greatly simplified, the moving stability of the drill rod 1 is improved, and the vibration amplitude of the drill rod 1 is reduced.

As shown in fig. 2, as a preferred embodiment, the drill rod drilling machine further comprises a rotating drum 7 sleeved outside the drill rod 1, a plurality of guide rails 8 and two support rings 9 are arranged on the inner wall of the rotating drum 7, a plurality of groups of pushing plates 10 are arranged on the inner wall of the support rings 9 in an inclined and rotating manner, each group of pushing plates 10 consists of two pushing plates 10, and the outer ends of the pushing plates 10 are rotatably installed on the outer wall of the segmental plate 4.

Specifically, the guide rails 8 are parallel to the drill rod 1 and fixed on the inner wall of the rotary drum 7, one support ring 9 is fixed on the inner wall of the rotary drum 7, the other support ring 9 is slidably mounted on the guide rails 8, the guide rails 8 guide the support ring 9 thereon, so that the support ring 9 can move stably and can avoid the inclination of the support ring when moving, two push plates 10 in each set of push plates 10 are parallel to each other and incline, the support ring 9, the two push plates 10 and the outer side wall of the segmental plate 4 form a parallelogram, the inclination directions of the push plates 10 in the two support rings 9 are opposite, two sets of push plates 10 are mounted on the segmental plate 4, the two sets of push plates 10 are respectively mounted on the two support rings 9, the directions of the parallels formed by the two sets of push plates 10 on the segmental plate 4 are opposite, the segmental plate 4 can move in a translational manner through the parallels, the support rings 9 on the guide rails 8 drive the segmental plates 4 to move synchronously, can realize the synchronous centre gripping work to drilling rod 1, conveniently fix a position the processing to the drilling rod 1 of moving state, improve the drilling precision, simultaneously because the adjustable removal of a plurality of bow-shaped plates 4 to make things convenient for equipment to adopt the drilling rod 1 of different specification widths to carry out drilling work.

In this embodiment, the support ring 9 on the push guide rail 8 moves, this support ring 9 drives the segmental plate 4 through every group top push pedal 10 on it and removes, every group top push pedal 10 on another support ring 9 can support the segmental plate 4 in step, thereby guarantee that the segmental plate 4 can realize translational motion, conveniently make two extrusion wheels 5 on the segmental plate 4 can contact with drilling rod 1 simultaneously, improve the stability that segmental plate 4 and extrusion wheel 5 removed, when avoiding the segmental plate 4 slope, two extrusion wheels 5 can't contact with drilling rod 1 simultaneously and lead to unable stable centre gripping transport work to the drilling rod 1 realization on it, improve equipment operating stability and fastness, rotate rotary drum 7, rotary drum 7 can drive a plurality of segmental plates 4 synchronous rotations, thereby drive drilling rod 1 and rotate.

As shown in fig. 2, as a preferred embodiment, the drill rod drilling machine further comprises an outer fixed cylinder 11, the drill rod 1 passes through the outer fixed cylinder 11 and moves, the rotary drum 7 is rotatably mounted on the inner wall of the outer fixed cylinder 11, a plurality of first air cylinders 12 are mounted on the inner wall of the rotary drum 7, the movable ends of the first air cylinders 12 are connected with the support ring 9 on the guide rail 8, a rotating motor 13 is mounted on the top of the outer fixed cylinder 11, a first gear 14 is arranged at the output end of the rotating motor 13, teeth are arranged on the circumferential inner wall of the rotary drum 7, and the first gear 14 is meshed with the teeth on the rotary drum 7.

In this embodiment, the outer fixed cylinder 11 can support the rotary cylinder 7, the first cylinder 12 can push the support ring 9 on the guide rail 8 to move, so as to drive the plurality of segmental plates 4 to move synchronously, and the rotating motor 13 drives the rotary cylinder 7 to rotate through the first gear 14, so as to drive the drill rod 1 and the drill bit 2 to rotate.

As shown in fig. 1 and 4, as a preferable embodiment, the drill rod drilling machine further includes a conveying cylinder 15, the conveying cylinder 15 is located at one end of the tail portion of the drill rod 1, both ends of the conveying cylinder 15 are rotatably provided with a rotating ring 16, the inner wall of the rotating ring 16 is provided with a plurality of second air cylinders 17, the movable end of each second air cylinder 17 is provided with a clamping plate 18, the outer wall of the conveying cylinder 15 is provided with a plurality of third air cylinders 19, and the fixed end of each third air cylinder 19 is arranged on the outer wall of the outer fixed cylinder 11.

Specifically, the conveying cylinder 15 is coaxial with the outer fixed cylinder 11, a plurality of second cylinders 17 in the rotating ring 16 are distributed annularly, the second cylinders 17 are arranged in the radial direction of the rotating ring 16, the number of the second cylinders 17 is four, the clamping plate 18 is used for extruding and fixing the next drill rod 1 to be butted, and the third cylinder 19 can drive the conveying cylinder 15 to move up and down.

In the embodiment, a drill rod 1 to be butted penetrates through a conveying cylinder 15 and two rotating rings 16, a plurality of second air cylinders 17 in the rotating rings 16 push a plurality of clamping plates 18 to move and extrude and fix the drill rod 1 in the conveying cylinder 15, so that the drill rod 1 is fixed on the conveying cylinder 15, the two rotating rings 16 are rotated, the two rotating rings 16 drive the drill rod 1 in the conveying cylinder 15 to rotate and enable the drill rod 1 in the conveying cylinder 15 and the drill rod 1 in the outer fixed cylinder 11 to have the same rotating speed, the conveying cylinder 15 is pushed to move through a third air cylinder 19, so that the drill rod 1 in the conveying cylinder 15 moves towards the drill rod 1 in the outer fixed cylinder 11, the drill rod 1 in the conveying cylinder 15 is butted on the drill rod 1 in the outer fixed cylinder 11 through a quick connector 3, the drill rod 1 finishes the butting work under the rotating condition, the continuous drilling work of the drill rod 1 and the drill bit 2 is ensured, the working efficiency is improved, and the time loss when the machine is stopped and the drill rod 1 is butted is avoided, guarantee equipment continuous operation, avoid the equipment to carry out mechanical loss when frequent sound conversion simultaneously, improve equipment life to when reducing drill bit 2 and drilling, the drilling resistance when it changes into the developments from static, conveniently protect drill bit 2.

As shown in fig. 4, as a preferred embodiment, a first telescopic rod 20 is disposed between two adjacent second cylinders 17 in the rotating ring 16, a corner guide plate 21 is fixed to a movable end of the first telescopic rod 20, and two ends of the corner guide plate 21 are respectively inserted into two adjacent clamping plates 18 in a sliding manner.

In this embodiment, when a splint 18 in the rotating ring 16 moves, it drives the turning guide plate 21 to move, the first telescopic rod 20 performs telescopic motion and guides the turning guide plate 21, the turning guide plate 21 synchronously drives another adjacent splint 18 to move, so that the purpose of synchronously moving a plurality of splints 18 in the rotating ring 16 is realized, the drill rod 1 between the plurality of splints 18 is conveniently positioned, and the coincidence of the axis of the drill rod 1 in the conveying cylinder 15 and the axis of the drill rod 1 in the outer fixing cylinder 11 is ensured.

As shown in fig. 1, as a preferred embodiment of the above embodiment, a synchronous motor 22 and a dual output shaft reducer 23 are mounted on an outer wall of the conveying cylinder 15, the synchronous motor 22 is in transmission connection with the dual output shaft reducer 23, two output ends of the dual output shaft reducer 23 are both fixed with a rotating shaft 24, an outer end of the rotating shaft 24 is fixed with a second gear 25, teeth are arranged on an outer circumferential wall of the rotating ring 16, and the second gear 25 is in meshing connection with the teeth on the rotating ring 16.

In this embodiment, the synchronous motor 22 drives the rotating rings 16 to rotate through the dual output shaft reducer 23, the rotating shaft 24 and the second gear 25, so as to drive the drill rod 1 to be butted in the conveying cylinder 15 to rotate, thereby ensuring that the drill rod 1 in the conveying cylinder 15 and the drill rod 1 in the outer fixed cylinder 11 rotate at the same speed, and the two rotating rings 16 rotate synchronously.

As shown in fig. 5, as a preferred embodiment of the present invention, a clamping cylinder 26 is rotatably mounted on the end portion of the outer fixed cylinder 11 facing the drill bit 2, a plurality of second telescopic rods 27 are fixed on the inner wall of the clamping cylinder 26, the second telescopic rods 27 are along the radial direction of the clamping cylinder 26, an arch 28 is fixed on the movable end of the second telescopic rods 27, a guide wheel 29 is rotatably mounted on the arch 28, the guide wheel 29 is in pressing contact with the outer wall of the drill rod 1, a moving ring 30 is slidably disposed in the clamping cylinder 26, a plurality of top pressing plates 31 and a plurality of plate springs 32 are disposed on the inner wall of the moving ring 30, the top pressing plates 31 are rotatably connected with the moving ring 30, the top pressing plates 31 are inclined, the outer ends of the top pressing plates 31 are rotatably mounted on the arch 28, and the outer ends of the plate springs 32 are fixed on the inner wall of the clamping cylinder 26.

In this embodiment, the number of the second telescopic rods 27, the bow-shaped frames 28 and the guide wheels 29 is four, the plate spring 32 pulls the moving ring 30 to slide in the clamping cylinder 26, the moving ring 30 pushes the bow-shaped frames 28 and the guide wheels 29 to move through the jacking plate 31, so that the guide wheels 29 and the drill rods 1 cling to the guide wheels 29 to synchronously extrude and fix the drill rods 1, thereby realizing synchronous clamping and fixing work on the drill rods 1, and meanwhile, the guide wheels 29 synchronously move to realize positioning work on the drill rods 1, the second telescopic rods 27 can perform telescopic motion and support and guide the bow-shaped frames 28, when the drill rods 1 rotate, the drill rods 1 drive the clamping cylinders 26 to rotate on the outer fixing cylinders 11, and when the drill rods 1 drill, the drill rods 1 drive the guide wheels 29 to rotate.

As shown in fig. 2, as a preferred embodiment, an annular bin 33 is installed on one side of the inner wall of the outer fixed cylinder 11 facing the drill bit 2, a plurality of spray pipes 34 are obliquely and communicatively arranged on the inner wall of the annular bin 33, the spray pipes 34 are obliquely and directionally facing the drill bit 2, a water inlet pipe 35 is fixed on the outer wall of the outer fixed cylinder 11, and the water inlet pipe 35 is communicated with the annular bin 33.

In this embodiment, in external water passed through inlet tube 35 pump income annular storehouse 33, the water in the annular storehouse 33 passes through on spray tube 34 slope blowout to the outer wall of drilling rod 1, and after drilling work accomplished, when drilling rod 1 promoted, can wash drilling rod 1 outer wall through spray tube 34 water spray to clear up the silt impurity on drilling rod 1 outer wall, avoid in its entering equipment and cause the influence to the equipment operation.

The above description is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, several modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be regarded as the protection scope of the present invention.

Claims (8)

1. The utility model provides a coal mining area water damage discharges and uses high stable drilling equipment, a serial communication port, including drilling rod (1), drill bit (2) and express joint piece (3), a plurality of tooth's sockets have been seted up on the outer wall of drilling rod (1), the head in drilling rod (1) is installed in drill bit (2), the afterbody in drilling rod (1) is installed in express joint piece (3), direction is provided with a plurality of segmental plates (4) around drilling rod (1), segmental plate (4) internal rotation is provided with two extrusion wheels (5), be provided with the tooth on extrusion wheel (5) circumference outer wall, tooth and the tooth meshing on drilling rod (1) on the extrusion wheel (5), be provided with on the outer wall of one of them segmental plate (4) and carry motor (6), carry motor (6) and be connected rather than extrusion wheel (5) transmission in segmental plate (4).

2. The high-stability drilling equipment for water disaster emission in the coal mining area according to claim 1, further comprising a rotary drum (7) sleeved outside the drill rod (1), wherein a plurality of guide rails (8) and two support rings (9) are arranged on the inner wall of the rotary drum (7), a plurality of groups of top push plates (10) are obliquely and rotatably arranged on the inner wall of the support rings (9), each group of top push plates (10) consists of two top push plates (10), and the outer ends of the top push plates (10) are rotatably arranged on the outer wall of the cambered plate (4).

3. The high-stability drilling equipment for water disaster emission in the coal mining area according to claim 2, further comprising an outer fixed cylinder (11), wherein the drill rod (1) penetrates through the outer fixed cylinder (11) and moves, the rotary cylinder (7) is rotatably installed on the inner wall of the outer fixed cylinder (11), a plurality of first air cylinders (12) are installed on the inner wall of the rotary cylinder (7), the movable ends of the first air cylinders (12) are connected with the support rings (9) on the guide rails (8), the top of the outer fixed cylinder (11) is provided with a rotary motor (13), the output end of the rotary motor (13) is provided with a first gear (14), the inner wall of the circumference of the rotary cylinder (7) is provided with teeth, and the first gear (14) is meshed with the teeth on the rotary cylinder (7).

4. The high-stability drilling equipment for water disaster emission in the coal mining area according to claim 3, further comprising a conveying cylinder (15), wherein the conveying cylinder (15) is located on one side of the tail part of the drill rod (1), rotating rings (16) are rotatably mounted at two ends of the conveying cylinder (15), a plurality of second air cylinders (17) are mounted on the inner wall of each rotating ring (16), clamping plates (18) are mounted at movable ends of the second air cylinders (17), a plurality of third air cylinders (19) are mounted on the outer wall of the conveying cylinder (15), and fixed ends of the third air cylinders (19) are mounted on the outer wall of the outer fixing cylinder (11).

5. The high-stability drilling equipment for water disaster emission in the coal mining area is characterized in that a first telescopic rod (20) is arranged between two adjacent second cylinders (17) in the rotating ring (16), a corner guide plate (21) is fixed at the movable end of the first telescopic rod (20), and two ends of the corner guide plate (21) are respectively inserted into two adjacent clamping plates (18) in a sliding mode.

6. The high-stability drilling equipment for water disaster emission in the coal mining area according to claim 5, wherein a synchronous motor (22) and a double-output-shaft reducer (23) are installed on the outer wall of the conveying cylinder (15), the synchronous motor (22) is in transmission connection with the double-output-shaft reducer (23), rotating shafts (24) are fixed on two output ends of the double-output-shaft reducer (23), second gears (25) are fixed on the outer ends of the rotating shafts (24), teeth are arranged on the circumferential outer wall of the rotating ring (16), and the second gears (25) are in meshing connection with the teeth on the rotating ring (16).

7. The high-stability drilling equipment for water disaster emission in the coal mining area according to claim 6, wherein the outer fixed cylinder (11) is rotatably provided with a clamping cylinder (26) towards the end part of the drill bit (2), the inner wall of the clamping cylinder (26) is fixed with a plurality of second telescopic rods (27), the second telescopic rods (27) are arranged along the radial direction of the clamping cylinder (26), the movable end of each second telescopic rod (27) is fixed with an arch-shaped frame (28), the arch-shaped frame (28) is rotatably provided with a guide wheel (29), the guide wheel (29) is in pressing contact with the outer wall of the drill rod (1), the clamping cylinder (26) is internally provided with a movable ring (30) in a sliding manner, the inner wall of the movable ring (30) is provided with a plurality of top pressure plates (31) and a plurality of plate springs (32), the top pressure plates (31) are rotatably connected with the movable ring (30), the top pressure plates (31) are inclined, the outer ends of the top pressure plates (31) are rotatably arranged on the arch-shaped frames (28), the outer end of the plate spring (32) is fixed on the inner wall of the clamping cylinder (26).

8. The high-stability drilling equipment for water disaster emission in the coal mining area according to claim 7, wherein an annular bin (33) is installed on one side, facing the drill bit (2), of the inner wall of the outer fixing cylinder (11), a plurality of spray pipes (34) are arranged on the inner wall of the annular bin (33) in an inclined communication mode, the spray pipes (34) are inclined towards the drill bit (2), a water inlet pipe (35) is fixed on the outer wall of the outer fixing cylinder (11), and the water inlet pipe (35) is communicated with the annular bin (33).

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