CN211148094U

CN211148094U - Sampling device for geological exploration

Info

Publication number: CN211148094U
Application number: CN201922055848.5U
Authority: CN
Inventors: 耿安凯
Original assignee: First Geological Brigade of Shandong Provincial Bureau of Geology and Mineral Resources of First Geological and Mineral Exploration Institute of Shandong Province
Current assignee: First Geological Brigade of Shandong Provincial Bureau of Geology and Mineral Resources of First Geological and Mineral Exploration Institute of Shandong Province
Priority date: 2019-11-26
Filing date: 2019-11-26
Publication date: 2020-07-31
Anticipated expiration: 2029-11-26

Abstract

The utility model discloses a sampling device for geological exploration, which comprises a wheel, a supporting plate, drive mechanism, supporting mechanism, first rotation section of thick bamboo, a second rotation section of thick bamboo and third rotation section of thick bamboo, backup pad bottom four corners all is equipped with the supporting legs that the specification is the same and keeps swing joint with the backup pad, the wheel sets up in one side of supporting legs, the wheel top passes through screwed connection with the backup pad, drive mechanism installs in the top one end of backup pad, supporting mechanism installs in backup pad top intermediate position, first rotation section of thick bamboo nestification sets up in the supporting mechanism bottom, a second rotation section of thick bamboo and first rotation section of thick bamboo bottom nested connection, a third rotation section of thick bamboo rotates a bottom nested connection with the second, stretch into the underground through a plurality of rotary drums and take a sample deep earth's surface, the understanding geological conditions that can be better, the accuracy.

Description

Sampling device for geological exploration

Technical Field

The utility model relates to a geological sampling device technical field specifically says a sampling device for geological exploration.

Background

Geology generally refers to the properties and characteristics of the earth, mainly refers to the material composition, structure, development history and the like of the earth, and comprises the difference of the layers of the earth, physical properties, chemical properties, rock properties, mineral components, the output states and contact relations of rock stratums and rock masses, the structure development history, the biological evolution history and the climate change history of the earth, the occurrence conditions and the distribution rules of mineral resources and the like.

However, the existing geological sampling device can only sample the earth surface generally, and cannot sample the deep layer of the earth surface, so that the geological test result in the region is inaccurate.

SUMMERY OF THE UTILITY MODEL

Therefore, in order to solve the above-mentioned not enough, the utility model provides a sampling device for prospecting herein stretches into the underground through a plurality of rotary drums and takes a sample to the earth's surface deep layer, understanding geology condition that can be better has improved the accuracy of geological test result.

The utility model discloses a realize like this, construct a sampling device for prospecting, which comprises a wheel, a supporting plate, drive mechanism, supporting mechanism, first rotation section of thick bamboo, a second rotation section of thick bamboo and third rotation section of thick bamboo, backup pad bottom four corners all is equipped with the same supporting legs of specification and keeps swing joint with the backup pad, the wheel sets up in one side of supporting legs, the wheel top passes through screwed connection with the backup pad, drive mechanism installs in the top one end of backup pad, supporting mechanism installs in backup pad top intermediate position, first rotation section of thick bamboo nestification sets up in the supporting mechanism bottom, a second rotation section of thick bamboo and first rotation section of thick bamboo bottom nested connection, a third rotation section of thick bamboo rotates a bottom nested connection with the second.

Furthermore, the traction mechanism comprises a first motor, a rotating shaft, a support frame and a steel wire rope, wherein the first motor is arranged at one end of the top of the support plate and is connected with the support plate through a screw, one end of the rotating shaft penetrates through the support frame and is movably connected with the support frame, the other end of the rotating shaft is welded with a motor shaft of the first motor, the support frame is arranged at one side of the first motor through a screw, the steel wire rope is wound on the outer side of the rotating shaft, and one end of the steel wire rope is provided with a plurality of connecting steel wires; the rotating shaft connected with the first motor is driven to rotate by controlling the first motor to work, the steel wire rope wound on the outer side of the rotating shaft rotates along with the rotating shaft, the rotating shaft tightens the steel wire rope to pull the steel wire rope, one end of the steel wire rope rotates on the outer side of the fixed pulley, the connecting steel wire rope connected with the steel wire rope moves upwards, and the first motor is a Y250 three-phase asynchronous alternating current motor with a speed reducer.

Furthermore, the supporting mechanism comprises a lifting plate, a second motor, a rotating disc, a fixed pulley and a cross beam, wherein two ends of the bottom of the cross beam are respectively provided with a supporting rod with the same specification and are connected with the cross beam through screws, the bottom of the supporting rod is connected with the supporting plate through screws, two ends of a lifting plate nest are nested outside the supporting rods and are movably connected with the supporting rods, four corners of the top of the lifting plate are respectively provided with a clamping plate with the same specification and are welded with the lifting plate, the second motor is arranged in the middle position of the top of the lifting plate and is connected with the lifting plate through screws, the rotating disc penetrates through the middle position of the lifting plate and is movably connected with the lifting plate, one end of the rotating disc is welded with a motor shaft of the second motor, the fixed pulley is arranged in the middle position of the bottom of the cross beam and is movably connected with the cross beam, the bottom of the rotating disc is provided with a plurality of first limiting rods with, one end of the connecting steel rope is welded with the clamping plate; move up through the pulling connecting steel cable, drive the lifter plate with the buckle plate of connecting steel cable connection and move up, the second motor at lifter plate top is followed and is up moved, drives the rolling disc rotation rather than being connected through controlling second motor work, and the Y280 three-phase asynchronous AC motor of second motor for having the reduction gear to sample the deep layer of earth's surface, understanding geological conditions that can be better.

Furthermore, the first rotating cylinder comprises a first rotating rod, a handle, a second rotating disc and a movable groove, the movable groove is hollowed out of the first rotating cylinder, the first rotating rod is arranged at the bottom of the second rotating disc and is connected with the second rotating disc through screws, the handle is nested on the outer side of the first rotating cylinder and is connected to the second rotating disc, the handle is welded with the second rotating disc, the second rotating disc is nested on the inner side of the first rotating cylinder and is movably connected with the first rotating cylinder, a plurality of first limiting holes with the same specification are hollowed out of the top of the first rotating cylinder, and the first limiting rod is nested on the inner side of the first limiting holes; with the nestification of first section of thick bamboo rotation in second rolling disc bottom, at this moment, first spacing hole and the laminating of first gag lever post outside, cooperation external motor rotates the handle and makes it drive the second rolling disc and rotate, and at this moment, the handle is at the activity inslot activity, follows the rotation with the first rotation pole that the second rolling disc is connected to sample the earth's surface deep layer, understanding geological conditions that can be better.

Furthermore, the second rotating cylinder comprises a second rotating rod, a plurality of second limiting holes with the same specification are hollowed in the top of the second rotating cylinder, the second rotating rod is nested in the inner side of the second rotating cylinder and is movably connected with the second rotating cylinder, a plurality of second limiting rods with the same specification are arranged at the bottom of the second rotating cylinder and are welded with the second rotating cylinder, and a plurality of screw rods with the same specification are arranged on the outer side of the second rotating cylinder and are movably connected with the second rotating cylinder; rotating a section of thick bamboo nestification first rotation bobbin base portion with the second, it is the same with second rotation bobbin base portion structure to need to notice first rotation bobbin base portion structure, first rotation pole and second dwang nested connection, pass the second through the screw rod and rotate a section of thick bamboo outside and first rotation bobbin outside, it is fixed to make first rotation bobbin and second rotate a section of thick bamboo, first rotation bobbin and second rotation bobbin stability at the rotation in-process has been strengthened, survey the underground degree of depth as required and use the second rotation bobbin, it is more to survey the second rotation bobbin of using deepening, thereby stretch into the underground through a plurality of rotary drums and take a sample to the earth's surface deep layer, understanding geological conditions that can be better, the accuracy of geological examination result has been improved.

Further, the third rotating cylinder comprises a third rotating rod, a feeding hole, a baffle, a drill bit and a discharging hole, a plurality of third limiting holes with the same specification are hollowed in the top of the third rotating cylinder, the third rotating rod is nested in the third rotating cylinder and is movably connected with the third rotating cylinder, the feeding hole is hollowed in the outer side of the third rotating cylinder, the baffle is welded with one end of the third rotating rod through a connecting rod, the drill bit is arranged at the bottom of the third rotating cylinder and is connected with the third rotating cylinder through a screw, and the discharging hole is hollowed in the bottom position of the outer side of the third rotating cylinder; rotate a section of thick bamboo bottom nested connection with the third with the second, pass the second through the screw rod and rotate a section of thick bamboo outside and first third and rotate a section of thick bamboo outside, it is fixed to make second rotate a section of thick bamboo and third and rotate a section of thick bamboo, the stability of second rotation a section of thick bamboo and third rotation section of thick bamboo in the rotation process has been strengthened, second dwang and third dwang nested connection, when needs sample, it drives the baffle rotation to rotate the third dwang, make the feed inlet do not have the obstacle, earth gets into from the feed inlet, after having taken a sample, block the feed inlet with the baffle, rotate a section of thick bamboo through rotating ground to the third, the earth of sample spills through the discharge gate, thereby stretch into the underground through a plurality of rotary drums and take a sample deep earth's surface, understanding geological conditions that can be better.

Furthermore, the supporting plate comprises a hollow groove, the hollow groove is arranged on the inner side of the supporting plate in a hollowed manner, and two side surfaces of the hollow groove are respectively provided with a movable plate with the same specification and are movably connected with the hollow groove; the supporting plate arranged is used for limiting the first rotating barrel, and the first rotating barrel is prevented from shaking.

The utility model discloses a plurality of rotary drums stretch into the underground and take a sample to the earth's surface deep layer, understanding geological conditions that can be better has improved the accuracy of geological test result, and concrete advantage embodies:

the method has the advantages that: the rotating shaft connected with the first motor is driven to rotate by controlling the first motor to work, the steel wire rope wound outside the rotating shaft is driven to rotate, the rotating shaft tightens the steel wire rope, the steel wire rope is pulled by the rotating shaft, one end of the steel wire rope rotates outside the fixed pulley, the steel wire rope connected with the steel wire rope moves upwards, the first motor is a Y250 three-phase asynchronous alternating current motor with a speed reducer, the steel wire rope moves upwards by pulling, a clamping plate connected with the connecting steel wire rope drives a lifting plate to move upwards, the second motor at the top of the lifting plate moves upwards by following, the rotating plate connected with the lifting plate is driven to rotate by controlling the second motor to work, and the second motor is a Y280 three-phase asynchronous alternating current motor with a speed.

The method has the advantages that: the first rotating cylinder is nested at the bottom of the rotating disc, at the moment, the first limiting hole is attached to the outer side of the first limiting rod, the handle is rotated by matching with an external motor to drive the rotating disc to rotate, at the moment, the handle moves in the movable groove, the first rotating rod connected with the rotating disc rotates along with the handle, the second rotating cylinder is nested at the bottom of the first rotating cylinder, attention is needed to be paid that the bottom structure of the first rotating cylinder is the same as that of the bottom of the second rotating cylinder, the first rotating rod and the second rotating rod are connected in a nested mode, the screw penetrates through the outer side of the second rotating cylinder and the outer side of the first rotating cylinder, the first rotating cylinder and the second rotating cylinder are fixed, the stability of the first rotating cylinder and the second rotating cylinder in the rotating process is enhanced, the second rotating cylinder is used according to the required underground depth, and the number of the second rotating cylinders is increased when the detection.

The method has the advantages that: rotate a section of thick bamboo and second with the third and rotate bobbin base nested connection, pass the second through the screw rod and rotate a section of thick bamboo outside and the first third and rotate a section of thick bamboo outside, it is fixed to make second rotate a section of thick bamboo and third and rotate a section of thick bamboo, the stability of second rotation a section of thick bamboo and third rotation section of thick bamboo in the rotation process has been strengthened, second dwang and third dwang nested connection, when needs sample, it drives the baffle rotation to rotate the third dwang, make the feed inlet do not have the obstacle, earth gets into from the feed inlet, after having taken a sample, block the feed inlet with the baffle, rotate a section of thick bamboo through rotating ground to the third, the earth of sample spills through the discharge gate, play limiting displacement to first rotation section of thick bamboo through the backup pad that.

Drawings

FIG. 1 is a schematic structural diagram of a sampling device for geological exploration according to the present invention;

FIG. 2 is an enlarged view of the portion A of FIG. 1;

FIG. 3 is a schematic structural view of a first rotary drum of the present invention;

FIG. 4 is a longitudinal sectional view of a first rotary cylinder according to the present invention;

FIG. 5 is a schematic structural view of a third rotary drum of the present invention;

fig. 6 is an enlarged view of a portion a in fig. 5 according to the present invention;

fig. 7 is a schematic view of a partial structure of the second rotating rod of the present invention.

Sequence numbers shown in the figures: the support leg 1, the wheel 2, the support plate 3, the hollow groove 31, the movable plate 32, the traction mechanism 4, the first motor 41, the rotating shaft 42, the support frame 43, the wire rope 44, the connecting wire rope 45, the support mechanism 5, the support rod 51, the lifting plate 52, the buckle plate 53, the second motor 54, the rotating disc 55, the fixed pulley 56, the cross beam 57, the first limiting rod 58, the first rotating cylinder 6, the first rotating rod 61, the handle 62, the first limiting hole 63, the second rotating disc 64, the movable groove 65, the second rotating cylinder 7, the second limiting hole 71, the second rotating rod 72, the second limiting rod 73, the screw 74, the third rotating cylinder 8, the third limiting hole 81, the third rotating rod 82, the feed port 83, the baffle 84, the drill bit 85 and the discharge port 86.

Detailed Description

The present invention will be described in detail below with reference to the attached drawings, and the technical solutions in the embodiments of the present invention will be clearly and completely described. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative efforts belong to the protection scope of the present invention; furthermore, the terms "first," "second," "third," "upper, lower, left, right," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. Meanwhile, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "connected" and "connected" should be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; the connection can be mechanical connection or electrical connection; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

The utility model provides a sampling device for geological exploration through improvement, as shown in the attached drawing of the specification, the sampling device can be implemented as follows; the wheel type vehicle wheel traction mechanism comprises a wheel 2, a supporting plate 3, a traction mechanism 4, a supporting mechanism 5, a first rotating cylinder 6, a second rotating cylinder 7 and a third rotating cylinder 8, wherein four corners of the bottom of the supporting plate 3 are respectively provided with supporting legs 1 with the same specification and are movably connected with the supporting plate 3, the wheel 2 is arranged on one side of the supporting legs 1, the top of the wheel 2 is connected with the supporting plate 3 through screws, the traction mechanism 4 is arranged at one end of the top of the supporting plate 3, the supporting mechanism 5 is arranged in the middle position of the top of the supporting plate 3, the first rotating cylinder 6 is nested at the bottom end of the supporting mechanism 5, the second rotating cylinder 7 is nested with the bottom end of the first rotating cylinder 6, and the third rotating;

more specifically, the traction mechanism 4 includes a first motor 41, a rotating shaft 42, a support frame 43 and a steel wire rope 44, the first motor 41 is disposed at one end of the top of the support plate 3 and is connected with the support plate 3 through a screw, one end of the rotating shaft 42 penetrates through the support frame 43 and is movably connected with the support frame 43, the other end of the rotating shaft 42 is welded with a motor shaft of the first motor 41, the support frame 43 is mounted at one side of the first motor 41 through a screw, the steel wire rope 44 is wound on the outer side of the rotating shaft 42, and one end of the steel wire rope 44 is provided with a plurality of connecting steel wires 45; the rotating shaft 42 connected with the first motor 41 is driven to rotate by controlling the first motor 41 to work, the steel wire rope 44 wound on the outer side of the rotating shaft 42 rotates along with the rotating shaft 42, the steel wire rope 44 is tightened by the rotating shaft 42, the steel wire rope 44 is pulled, one end of the steel wire rope 44 rotates on the outer side of the fixed pulley 56, the connecting steel wire rope 45 connected with the steel wire rope 44 moves upwards, and the first motor 41 is a Y250 three-phase asynchronous alternating current motor with a speed reducer;

more specifically, the supporting mechanism 5 comprises a lifting plate 52, a second motor 54, a rotating disc 55, a fixed pulley 56 and a cross beam 57, wherein two ends of the bottom of the cross beam 57 are respectively provided with a supporting rod 51 with the same specification and are connected with the cross beam 57 through screws, the bottom of the supporting rod 51 is connected with the supporting plate 3 through screws, two nested ends of the lifting plate 52 are nested outside the supporting rod 51 and are movably connected with the supporting rod 51, four corners of the top of the lifting plate 52 are respectively provided with a buckling plate 53 with the same specification and are welded with the lifting plate 52, the second motor 54 is arranged in the middle of the top of the lifting plate 52 and is connected with the lifting plate 52 through screws, the rotating disc 55 penetrates through the middle of the lifting plate 52 and is movably connected with the lifting plate 52, one end of the rotating disc 55 is welded with a motor shaft of the second motor 54, the fixed pulley 56 is arranged in the middle of the bottom of the cross beam 57 and is movably connected with the cross beam 57, the bottom, in addition, one end of the steel wire rope 44 is attached to the outer side of the fixed pulley 56 and is movably connected with the fixed pulley 56, and one end of the connecting steel rope 45 is welded with the buckle plate 53; the connecting steel rope 45 is pulled to move upwards, the buckle plate 53 connected with the connecting steel rope 45 drives the lifting plate 52 to move upwards, the second motor 54 on the top of the lifting plate 52 moves upwards along with the lifting, the second motor 54 is controlled to work to drive the rotating disc 55 connected with the second motor to rotate, and the second motor 54 is a Y280 three-phase asynchronous alternating current motor with a speed reducer;

more specifically, the first rotating cylinder 6 comprises a first rotating rod 61, a handle 62, a second rotating disc 64 and a movable groove 65, the movable groove 65 is arranged at the outer side of the first rotating cylinder 6 in a hollow manner, the first rotating rod 61 is arranged at the bottom of the second rotating disc 64 and is connected with the second rotating disc 64 through screws, the handle 62 is nested at the outer side of the first rotating cylinder 6 and is connected to the second rotating disc 64, the handle 62 is welded with the second rotating disc 64, the second rotating disc 64 is nested at the inner side of the first rotating cylinder 6 and is movably connected with the first rotating cylinder 6, a plurality of first limiting holes 63 with the same specification are arranged at the top of the first rotating cylinder 6 in a hollow manner, and the first limiting rod 58 is nested at the inner side of the first limiting holes 63; the first rotating cylinder 6 is nested at the bottom of the rotating disc 55, at the moment, the first limiting hole 63 is attached to the outer side of the first limiting rod 58, the handle 62 is rotated by matching with an external motor to drive the second rotating disc 64 to rotate, at the moment, the handle 62 moves in the movable groove 65, and the first rotating rod 61 connected with the second rotating disc 64 rotates along with the handle;

more specifically, the second rotating cylinder 7 comprises a second rotating rod 72, a plurality of second limiting holes 71 with the same specification are hollowed in the top of the second rotating cylinder 7, the second rotating rod 72 is nested in the inner side of the second rotating cylinder 7 and is movably connected with the second rotating cylinder 7, a plurality of second limiting rods 73 with the same specification are arranged at the bottom of the second rotating cylinder 7 and are welded with the second rotating cylinder 7, and a plurality of screw rods 74 with the same specification are arranged on the outer side of the second rotating cylinder 7 and are movably connected with the second rotating cylinder 7; the second rotating cylinder 7 is nested at the bottom of the first rotating cylinder 6, it is noted that the bottom structure of the first rotating cylinder 6 is the same as that of the second rotating cylinder 7, the first rotating rod 61 and the second rotating rod 72 are nested and connected, the first rotating cylinder 6 and the second rotating cylinder 7 are fixed by the screw 74 penetrating through the outer side of the second rotating cylinder 7 and the outer side of the first rotating cylinder 6, the stability of the first rotating cylinder 6 and the second rotating cylinder 7 in the rotating process is enhanced, the second rotating cylinder 7 is used according to the underground depth to be detected, and the deeper the second rotating cylinders 7 are used more;

more specifically, the third rotating cylinder 8 comprises a third rotating rod 82, a feeding hole 83, a baffle 84, a drill bit 85 and a discharging hole 86, a plurality of third limiting holes 81 with the same specification are hollowed in the top of the third rotating cylinder 8, the third rotating rod 82 is nested in the third rotating cylinder 8 and is movably connected with the third rotating cylinder 8, the feeding hole 83 is hollowed out in the outer side of the third rotating cylinder 8, the baffle 84 is welded with one end of the third rotating rod 82 through a connecting rod, the drill bit 85 is arranged at the bottom of the third rotating cylinder 8 and is connected with the third rotating cylinder 8 through a screw, and the discharging hole 86 is hollowed out in the bottom position of the outer side of the third rotating cylinder 8; the third rotating cylinder 8 is connected with the bottom of the second rotating cylinder 7 in a nested mode, the screw 74 penetrates through the outer side of the second rotating cylinder 7 and the outer side of the first third rotating cylinder 8, the second rotating cylinder 7 and the third rotating cylinder 8 are fixed, the stability of the second rotating cylinder 7 and the third rotating cylinder 8 in the rotating process is enhanced, the second rotating rod 72 is connected with the third rotating rod 82 in a nested mode, when sampling is needed, the third rotating rod 82 is rotated to drive the baffle plate 84 to rotate, the feed port 83 is free of obstruction, soil enters from the feed port 83, after sampling is completed, the baffle plate 84 blocks the feed port 83, the third rotating cylinder 8 rotates to the ground, and the sampled soil passes through the feed port 86;

more specifically, the support plate 3 comprises a hollow groove 31, the hollow groove 31 is arranged at the inner side of the support plate 3 in a hollow manner, and two side surfaces of the hollow groove 31 are respectively provided with a movable plate 32 with the same specification and are movably connected with the hollow groove 31; the supporting plate 3 which is arranged plays a limiting role for the first rotating barrel 6, and the first rotating barrel 6 is prevented from shaking.

This sampling device for prospecting's theory of operation: starting a first motor 41 to pull a steel wire rope 44, supporting the steel wire rope 44 through a fixed pulley 56, pulling a connecting steel rope 45 upwards to drive a lifting plate 52 to move upwards, first nesting and connecting a third rotating cylinder 8 with a rotating disc 55, controlling a second motor 54 to work, loosening the steel wire rope 44 for a certain distance by controlling the first motor 41 to work, driving the third rotating cylinder 8 underground, moving the lifting plate 52 upwards, then respectively connecting two ends of a second rotating cylinder 7 with the rotating disc 55 and the third rotating cylinder 8, then using the second rotating cylinder 7 according to the underground depth required to be detected, driving the second rotating cylinder 7 into the ground one by one, finally driving a first rotating cylinder 6 underground, matching an external motor to rotate a handle 62 to drive a second rotating disc 64 to rotate, welding a first rotating rod 61 with the second rotating disc 64, and welding a first rotating rod 61, Two liang of interconnect of second dwang 72 and third dwang 82, when needing the sample, rotate third dwang 82 and drive baffle 84 and rotate, make feed inlet 83 not have the obstacle, earth gets into from feed inlet 83, after having taken a sample, block feed inlet 83 with baffle 84, rotate a section of thick bamboo 8 through rotating ground to the third, the earth of sample spills through discharge gate 86, backup pad 3 through the setting plays limiting displacement to first a section of thick bamboo 6, prevent that first a section of thick bamboo 6 from rocking.

In conclusion; sampling device for geological exploration compares with current sampling device for geological exploration, stretches into the underground through a plurality of rotary drums and takes a sample to the earth's surface deep layer, understanding geological conditions that can be better has improved the accuracy of geological survey result.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. The utility model provides a sampling device for geological prospecting, includes wheel (2), backup pad (3), drive mechanism (4), supporting mechanism (5), first a section of thick bamboo (6), a section of thick bamboo (7) are rotated to the second and a third rotates a section of thick bamboo (8), its characterized in that: the supporting legs (1) that the specification is the same are arranged at four corners of the bottom of the supporting plate (3) and are movably connected with the supporting plate (3), the wheels (2) are arranged on one side of the supporting legs (1), the tops of the wheels (2) are connected with the supporting plate (3) through screws, the traction mechanism (4) is installed at one end of the top of the supporting plate (3), the supporting mechanism (5) is installed at the middle position of the top of the supporting plate (3), the first rotating cylinder (6) is nested in the bottom end of the supporting mechanism (5), the second rotating cylinder (7) is nested in connection with the bottom end of the first rotating cylinder (6), and the third rotating cylinder (8) is nested in connection with the bottom end of the second rotating cylinder (7).

2. A sampling device for geological exploration, according to claim 1, characterized in that: traction mechanism (4) include first motor (41), axis of rotation (42), support frame (43) and wire rope (44), first motor (41) set up in backup pad (3) top one end and pass through screwed connection with backup pad (3), axis of rotation (42) one end is run through support frame (43) and is kept swing joint with support frame (43), the motor shaft welding of axis of rotation (42) other end and first motor (41), support frame (43) are installed in one side of first motor (41) through the screw, wire rope (44) are around rolling up in the outside of axis of rotation (42), wire rope (44) one end is equipped with the same connection steel cable (45) of a plurality of specifications and welds with wire rope (44).

3. A sampling device for geological exploration, according to claim 1, characterized in that: the supporting mechanism (5) comprises a lifting plate (52), a second motor (54), a rotating disc (55), a fixed pulley (56) and a cross beam (57), wherein two ends of the bottom of the cross beam (57) are respectively provided with a supporting rod (51) with the same specification and are connected with the cross beam (57) through screws, the bottom of the supporting rod (51) is connected with a supporting plate (3) through screws, two nested ends of the lifting plate (52) are nested at the outer side of the supporting rod (51) and are movably connected with the supporting rod (51), four corners of the top of the lifting plate (52) are respectively provided with a buckle plate (53) with the same specification and are welded with the lifting plate (52), the second motor (54) is arranged in the middle position of the top of the lifting plate (52) and is connected with the lifting plate (52) through screws, the rotating disc (55) penetrates through the middle position of the lifting plate (52) and is movably connected with the lifting plate (, one end of the rotating disc (55) is welded with a motor shaft of the second motor (54), the fixed pulley (56) is arranged in the middle of the bottom of the cross beam (57) and is movably connected with the cross beam (57), a plurality of first limiting rods (58) with the same specification are arranged at the bottom of the rotating disc (55) and are welded with the rotating disc (55), in addition, one end of a steel wire rope (44) is attached to the outer side of the fixed pulley (56) and is movably connected with the fixed pulley (56), and one end of a connecting steel wire rope (45) is welded with the buckle plate (53).

4. A sampling device for geological exploration, according to claim 1, characterized in that: the first rotating cylinder (6) comprises a first rotating rod (61), a handle (62), a second rotating disk (64) and a movable groove (65), the movable groove (65) is arranged at the outer side of the first rotating cylinder (6) in a hollow way, the first rotating rod (61) is arranged at the bottom of the second rotating disc (64) and is connected with the second rotating disc (64) through a screw, the handle (62) is nested on the outer side of the first rotating cylinder (6) and is connected to a second rotating disk (64), the handle (62) is welded with a second rotating disc (64), the second rotating disc (64) is nested and arranged at the inner side of the first rotating cylinder (6) and is movably connected with the first rotating cylinder (6), the top of the first rotating cylinder (6) is provided with a plurality of first limiting holes (63) with the same specification in a hollow mode, and the first limiting rod (58) is nested on the inner side of the first limiting holes (63).

5. A sampling device for geological exploration, according to claim 1, characterized in that: a section of thick bamboo (7) is rotated to the second includes second dwang (72), the fretwork of a second rotation section of thick bamboo (7) top is equipped with the spacing hole of the same second (71) of a plurality of specifications, second dwang (72) nestification sets up in the inboard of a second rotation section of thick bamboo (7) and rotates a section of thick bamboo (7) with the second and keep swing joint, a second rotation section of thick bamboo (7) bottom is equipped with the same second gag lever post (73) of a plurality of specifications and rotates a section of thick bamboo (7) welding with the second, the second rotates a section of thick bamboo (7) outside and is equipped with the same screw rod (74) of a plurality of specifications and rotates a section of thick bamboo (7) with the second and keep swing joint.

6. A sampling device for geological exploration, according to claim 1, characterized in that: a section of thick bamboo (8) is rotated to the third includes third dwang (82), feed inlet (83), baffle (84), drill bit (85) and discharge gate (86), a third rotation section of thick bamboo (8) top fretwork is equipped with the spacing hole of the third (81) that a plurality of specifications are the same, third dwang (82) nestification sets up in the third rotates the inboard of a section of thick bamboo (8) and rotates a section of thick bamboo (8) with the third and keep swing joint, feed inlet (83) fretwork sets up in the third and rotates the outside of a section of thick bamboo (8), baffle (84) are through connecting rod and third dwang (82) one end welding, drill bit (85) set up in the third and rotate the bottom of a section of thick bamboo (8) and rotate a section of thick bamboo (8) with the third and pass through screwed connection, discharge gate (86) fretwork sets up in the outside bottom position that.

7. A sampling device for geological exploration, according to claim 1, characterized in that: the supporting plate (3) comprises a hollow groove (31), the hollow groove (31) is arranged on the inner side of the supporting plate (3) in a hollow mode, and two side faces of the hollow groove (31) are respectively provided with a movable plate (32) with the same specification and are movably connected with the hollow groove (31).