CN111947975A - Geological exploration equipment for multi-point rock drilling sampling mixed collection - Google Patents

Abstract

The invention discloses geological exploration equipment for multi-point rock drilling, sampling, mixing and collecting, which comprises an exploration machine body, wherein a lifting cavity is arranged in the exploration machine body, a lifting screw rod is rotatably arranged between the upper wall and the lower wall of the lifting cavity, a lifting plate capable of moving up and down is arranged in the lifting cavity, the central position of the lifting plate is in threaded connection with the lifting screw rod, and a rotating cylinder with the same four mechanisms and distributed in an annular matrix arrangement mode relative to a rotating chain wheel is arranged in the lifting cavity. The occurrence of small probability detection errors is reduced, and the exploration accuracy is greatly improved.

Description

Geological exploration equipment for multi-point rock drilling sampling mixed collection

Technical Field

The invention relates to the technical field of geological exploration equipment, in particular to geological exploration equipment for multi-point rock drilling sampling mixed collection.

Background

In our daily life, the field of geological exploration is based on natural science and earth science as theoretical bases, engineering problems related to geological survey, general survey and exploration of mineral resources, and geological structures and geological backgrounds of major projects are main objects, general geological exploration equipment is fixed-point excavation and collection, and common geological exploration equipment only performs geological excavation and collection once in one place, and small-probability events often cause certain deviation in soil property detection. The present invention sets forth a device that solves the above problems.

Disclosure of Invention

The technical problem is as follows: the common geological exploration equipment cannot achieve the effect of multi-point sampling mixing, so that a certain deviation exists in geological soil exploration due to the fact that a small probability time occurs, and the exploration result deviates from the actual situation.

In order to solve the problems, the geological exploration equipment for multi-point rock drilling, sampling, mixing and collecting is designed in the embodiment, and the geological exploration equipment for multi-point rock drilling, sampling, mixing and collecting comprises an exploration machine body, wherein a lifting cavity is arranged in the exploration machine body, a lifting screw rod is rotatably arranged between the upper wall and the lower wall of the lifting cavity, a lifting plate capable of moving up and down is arranged in the lifting cavity, the central position of the lifting plate is in threaded connection with the lifting screw rod, four rotating cylinders which are identical in mechanism and distributed in an annular matrix arrangement mode relative to a rotating chain wheel are arranged in the lifting cavity, the rotating cylinders are respectively rotatably connected to the lifting plate, a transmission rotating shaft is rotatably arranged in the rotating cylinders, the transmission rotating shaft is in splined connection with the rotating cylinders, a rock storage cavity is arranged in the lower wall of the lifting cavity, and sliding chutes positioned below the rotating cylinders are respectively arranged at, the rotary cylinder extends downwards into the rock storage cavity and is fixedly connected with functional drill bits respectively, storage cavities which penetrate through the functional drill bits from left to right are arranged in the functional drill bits respectively, communicating plates which are arranged on the left side and the right side of the functional drill bits and can move up and down are arranged in the functional drill bits respectively, communicating cavities are arranged in the communicating plates, lifting moving cavities are arranged on the inner sides of the storage cavities, the lower ends of the communicating plates penetrate through the storage cavities and penetrate through the lifting moving cavities, movable supporting plates which can move up and down are arranged in the lifting moving cavities, the left end surfaces and the right end surfaces of the movable supporting plates are fixedly connected with the end surfaces of the communicating plates, which are close to one side of the rotary cylinder, four drilling cavities with downward openings are distributed in an annular matrix arrangement mode on the lower wall of the rock storage cavity and are respectively positioned below the, the closing plate is kept away from center of symmetry one side and is equipped with the rotation chamber, rotate between the intracavity front and back two walls and rotate the support pivot of containing the torsional spring, support pivot excircle terminal surface be close to center of symmetry side end face respectively with center of symmetry side end face fixed connection is kept away from to the closing plate, the movable plate that the intracavity top intermediate position was the same with the right side position mechanism respectively and was controlled about can be deposited to the rock, the catch bar that symmetry just around the removal board left end face was equipped with, the catch bar with storage chamber side face size is the same, the rock is deposited the intracavity lower wall and is equipped with the scraper blade that can the horizontal slip.

Preferably, the upper end surface of the lifting screw extends upwards and penetrates through the transmission cavity, a lifting motor is fixedly arranged in the upper wall of the transmission cavity and above the lifting screw, and the upper end of the lifting screw is in power connection with the lifting motor.

Preferably, a transmission cavity is formed in the upper wall of the lifting cavity, the upper end face of the transmission rotating shaft extends upwards to the transmission cavity and the fixedly connected with rotating chain wheels, the rotating chain wheels are arranged between the rotating chain wheels in a winding mode, the transmission cavity is formed in the upper wall of the transmission cavity and is located on the left front side, a rotating motor is fixedly arranged above the power shaft, and power is connected to the upper end of the power shaft and the rotating motor.

Preferably, each side the left side of the excircle end face of the rotating cylinder is located, a switching plate is fixedly arranged below the lifting plate, a switching cavity with a downward opening is arranged in the switching plate, a switching block capable of moving up and down is arranged in the switching cavity, a switching stay rope is fixedly connected to the upper end face of the switching block, and a switching spring is fixedly connected between the upper end face of the switching block and the upper end face of the switching cavity.

Preferably, the right side of the upper wall of the lifting moving cavity is communicated with a connecting cavity, a supporting lifting block capable of moving up and down is arranged in the connecting cavity, the lower end face of the supporting lifting block is fixedly connected with the upper end face of the moving supporting plate, the upper end face of the supporting lifting block is fixedly connected with a connecting spring between the end faces of the upper wall of the connecting cavity, the upper end face of the supporting lifting block is fixedly connected with a connecting spring, and the connecting spring is connected with the switching pull rope.

Preferably, the rock is deposited the intracavity and is rotated above between the two walls and be equipped with the movable threaded rod, the movable plate respectively with movable threaded rod threaded connection, the rock is deposited the intracavity right side wall internal fixation and is equipped with the function motor, movable threaded rod right-hand member power connect in the function motor.

Preferably, the intracavity left wall intercommunication is deposited to the rock and is equipped with the collection chamber, collect the intracavity lower wall and place the rock collecting box that is used for collecting the soil property rock, the rock is deposited the chamber antetheca intercommunication and is equipped with reciprocating cavity, reciprocating cavity is equipped with the reciprocal board that can the leftward movement, the terminal surface extends to before the scraper blade reciprocating intracavity and with reciprocating board rear wall terminal surface fixed connection, it is equipped with the rotation pivot to rotate between two walls around the reciprocating cavity upside, rotation pivot excircle terminal surface fixedly connected with rotates the disc, it has the backup pad to rotate disc rear end face hinged joint, sliding connection has the swinging arms in the backup pad, terminal surface under the swinging arms with reciprocating board up end hinged joint.

Preferably, the reciprocating cavity antetheca just is located the band pulley chamber that the carousel the place ahead was equipped with the slope of below right, the terminal surface extends to forward before the rotation pivot band pulley intracavity fixedly connected with driven pulleys, band pulley intracavity lower wall rotates and is equipped with driving pulley, driving pulley with around being equipped with the belt between the driven pulleys, driving pulley rear end face axle center fixedly connected with transmission shaft.

Preferably, a gear cavity is arranged in the rear wall of the belt wheel cavity, the transmission shaft extends backwards into the gear cavity and is fixedly connected with a driven bevel gear, a driving bevel gear meshed with the driven bevel gear is arranged on the left wall in the gear cavity in a rotating manner, a connecting rotating shaft is fixedly connected to the axis of the left end surface of the driving bevel gear, a ratchet cavity is arranged in the left wall of the gear cavity and is positioned on the right side of the functional motor, the left end surface of the connecting rotating shaft extends leftwards into the ratchet cavity and is fixedly connected with a ratchet wheel, an inner circular cavity with a leftward opening is arranged in the ratchet wheel, a ratchet clamping groove is arranged on the inner circular surface of the inner circular cavity, a power rotating shaft is arranged on the left wall of the ratchet cavity in a rotating manner, the right end of the power rotating shaft extends into the inner circular cavity, pawls which are bilaterally symmetrical are respectively arranged on the outer circular end surface of, when the pawl rotates anticlockwise, the pawl is not clamped with the inner cavity clamping groove.

The invention has the beneficial effects that: the rock fragment recovery device achieves the effect of rock fragment recovery by drilling and sampling the rock, so that the rock exploration sampling efficiency is higher, rock fragments are efficiently recovered by automatically closing and communicating the sampling space of the drill bit, and the rock fragments are uniformly collected after being finally mixed by the effect of multi-point sampling, so that the rock fragment detection of sampling and recovery is closer to actual data, the occurrence of small-probability detection errors is reduced, and the exploration accuracy is greatly improved.

Drawings

For ease of illustration, the invention is described in detail by the following specific examples and figures.

FIG. 1 is a schematic diagram of the overall structure of a multi-point rock drilling sampling hybrid gathering geological exploration apparatus of the present invention;

FIG. 2 is a schematic view of the structure in the direction "A-A" of FIG. 1;

FIG. 3 is a schematic view of the structure in the direction "B-B" of FIG. 1;

FIG. 4 is a schematic view of the structure in the direction "C-C" of FIG. 3;

FIG. 5 is a schematic view of the structure in the direction "D-D" of FIG. 3;

FIG. 6 is a schematic view of the structure in the direction "E-E" of FIG. 5;

FIG. 7 is an enlarged view of the structure of "F" of FIG. 1;

FIG. 8 is an enlarged view of the structure of "G" of FIG. 1;

FIG. 9 is a schematic view of the structure in the direction "H-H" of FIG. 8;

FIG. 10 is a schematic view of the structure in the direction "I-I" of FIG. 1.

Detailed Description

The invention will now be described in detail with reference to fig. 1-10, for ease of description, the orientations described below will now be defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

The invention relates to geological exploration equipment for multi-point rock drilling, sampling, mixing and collecting, which comprises an exploration machine body 11, wherein a lifting cavity 27 is arranged in the exploration machine body 11, a lifting screw 16 is rotatably arranged between the upper wall and the lower wall of the lifting cavity 27, a lifting plate 21 capable of moving up and down is arranged in the lifting cavity 27, the central position of the lifting plate 21 is in threaded connection with the lifting screw 16, a rotating cylinder 20 with the same four mechanisms and distributed in an annular matrix manner relative to a rotating chain wheel 13 is arranged in the lifting cavity 27, the rotating cylinders 20 are respectively and rotatably connected with the lifting plate 21, a transmission rotating shaft 19 is rotatably arranged in the rotating cylinder 20, the transmission rotating shaft 19 is in splined connection with the rotating cylinder 20, a rock storage cavity 28 is arranged in the lower wall of the lifting cavity 27, and sliding chutes 68 positioned below the rotating cylinder 20 are respectively arranged at the communication positions of the rock storage cavity 28, the rotary cylinder 20 extends downwards into the rock storage cavity 28 and is fixedly connected with functional drill bits 54 respectively, storage cavities 57 which penetrate through from left to right are arranged in the functional drill bits 54 respectively, communicating plates 55 which are arranged on the left side and the right side of the functional drill bits 54 and can move up and down are arranged in the functional drill bits 54 respectively, communicating cavities 56 are arranged in the communicating plates 55, lifting moving cavities 59 are arranged inside the storage cavities 57, the lower ends of the communicating plates 55 penetrate through the storage cavities 57 and penetrate through the lifting moving cavities 59, movable supporting plates 58 which can move up and down are arranged in the lifting moving cavities 59, the left and right end faces of the movable supporting plates 58 are fixedly connected with the end faces of the communicating plates 55 close to one side of the rotary cylinder 20 respectively, four drilling cavities 62 with downward openings are distributed in an annular matrix arrangement under the rock storage cavity 28 and located below the functional drill bits 54 respectively, it can overturn and have elastic closing plate 63 to creep into to be equipped with bilateral symmetry in the chamber 62, closing plate 63 keeps away from center of symmetry one side and is equipped with and rotates chamber 61, rotate and rotate the support pivot 60 who contains the torsional spring between the two walls around in the chamber 61, support pivot 60 excircle terminal surface be close to center of symmetry a side terminal surface respectively with center of symmetry a side terminal surface fixed connection is kept away from to closing plate 63, the rock is deposited the interior top intermediate position of 28 and is moved movable plate 26 about the same and can of right side position difference mechanism, movable plate 26 left end face is equipped with symmetrical just catch bar 25 around, catch bar 25 with storage chamber 57 side size is the same, the rock is deposited the interior lower wall of 28 and is equipped with ability horizontal slip's scraper blade 24.

Advantageously, the upper end of the lifting screw 16 extends upwards and penetrates through the transmission cavity 12, a lifting motor 15 is fixedly arranged in the upper wall of the transmission cavity 12 and above the lifting screw 16, and the upper end of the lifting screw 16 is in power connection with the lifting motor 15.

Beneficially, a transmission cavity 12 is arranged in the upper wall of the lifting cavity 27, the upper end faces of the transmission rotating shafts 19 respectively extend upwards into the transmission cavity 12 and are fixedly connected with rotating chain wheels 13, a transmission chain 14 is wound between the rotating chain wheels 13 on each side, a rotating motor 17 is fixedly arranged in the upper wall of the transmission cavity 12 and above the power shaft 18 on the left front side, and the upper end of the power shaft 18 is in power connection with the rotating motor 17.

Beneficially, a switching plate 49 is fixedly arranged on the left side of the end face of the outer circle of each rotating cylinder 20 and below the lifting plate 21, a switching cavity 51 with a downward opening is arranged in the switching plate 49, a switching block 53 capable of moving up and down is arranged in the switching cavity 51, a switching pull rope 50 is fixedly connected to the upper end face of the switching block 53, and a switching spring 52 is fixedly connected between the upper end face of the switching block 53 and the end face of the upper wall of the switching cavity 51.

Beneficially, a connecting cavity 66 is communicated with the right side of the upper wall of the lifting moving cavity 59, a supporting lifting block 67 capable of moving up and down is arranged in the connecting cavity 66, the lower end face of the supporting lifting block 67 is fixedly connected with the upper end face of the moving supporting plate 58, a connecting spring 65 is fixedly connected between the upper end face of the supporting lifting block 67 and the upper end face of the upper wall of the connecting cavity 66, a connecting spring 65 is fixedly connected with the upper end face of the supporting lifting block 67, and the connecting spring 65 is connected with the switching pull rope 50.

Advantageously, a movable threaded rod 69 is rotatably arranged above the left wall and the right wall in the rock storage cavity 28, the movable plates 26 are respectively in threaded connection with the movable threaded rods 69, a function motor 29 is fixedly arranged in the right wall of the rock storage cavity 28, and the right end of the movable threaded rod 69 is in power connection with the function motor 29.

Beneficially, the rock storage cavity 28 is provided with a collection cavity 22 in a communicating manner on the left wall, the rock collection box 23 for collecting soil rocks is placed on the lower wall in the collection cavity 22, the front wall of the rock storage cavity 28 is provided with a reciprocating cavity 41 in a communicating manner, the reciprocating cavity 41 is provided with a reciprocating plate 40 capable of moving left, the front end face of the scraper 24 extends forward into the reciprocating cavity 41 and is fixedly connected with the rear end face of the reciprocating plate 40, a rotating shaft 46 is rotatably arranged between the front wall and the rear wall of the upper side of the reciprocating cavity 41, the excircle end face of the rotating shaft 46 is fixedly connected with a rotating disc 43, the rear end face of the rotating disc 43 is hinged with a support plate 44, a swinging rod 45 is slidably connected with the support plate 44, and the lower end face of the swinging rod 45 is hinged with the upper end face of the reciprocating plate 40.

Beneficially, a pulley cavity 39 inclined to the lower right is arranged in the front wall of the reciprocating cavity 41 and in front of the rotating disc 43, the front end face of the rotating shaft 46 extends forwards to the inside of the pulley cavity 39 and is fixedly connected with a driven pulley 47, a driving pulley 38 is rotatably arranged on the lower wall in the pulley cavity 39, a belt 48 is wound between the driving pulley 38 and the driven pulley 47, and a transmission shaft 36 is fixedly connected to the axis of the rear end face of the driving pulley 38.

Beneficially, a gear cavity 34 is arranged in the rear wall of the pulley cavity 39, the transmission shaft 36 extends backwards into the gear cavity 34 and is fixedly connected with a driven bevel gear 35, a left wall in the gear cavity 34 is rotatably provided with a driving bevel gear 33 engaged with the driven bevel gear 35, the axis of the left end surface of the driving bevel gear 33 is fixedly connected with a connecting rotating shaft 70, a ratchet cavity 30 is arranged in the left wall of the gear cavity 34 and is located at the right side of the functional motor 29, the left end surface of the connecting rotating shaft 70 extends leftwards into the ratchet cavity 30 and is fixedly connected with a ratchet 32, an inner circular cavity 37 with a leftward opening is arranged in the ratchet 32, an inner circular surface of the inner circular cavity 37 is provided with a ratchet clamping groove, a power rotating shaft 31 is rotatably arranged in the left wall in the ratchet cavity 30, the right end of the power rotating shaft 31 extends into the inner circular cavity 37, pawls 42 with left-right symmetry are respectively arranged on the outer circular end surface of the, when the pawl 42 rotates clockwise, the pawl 42 is clamped with the clamping groove of the inner circular cavity 37 and drives the inner circular cavity to rotate, and when the pawl 42 rotates anticlockwise, the pawl 42 is not clamped with the clamping groove of the inner circular cavity 37.

The following detailed description of the steps of using the multi-point rock drilling sampling hybrid gathering geological exploration device in the present document is provided with reference to fig. 1 to 10: in the initial state, the lifting plate 21 is located at the upper limit position, the scraper 24 is located at the right limit position, the moving plate 26 is located at the right limit position, the switching block 53 is located at the upper limit position, the moving support plate 58 is located at the upper limit position, and the supporting lifting block 67 is located at the upper limit position.

When the multifunctional drilling machine works, the exploration machine body 11 is moved to an exploration position, the rotating motor 17 is started to drive the power shaft 18 to rotate, the power shaft 18 drives the left front rotating chain wheel 13 to rotate, each side rotating chain wheel 13 is driven to rotate through the transmission chain 14, the rotating chain wheel 13 rotates to drive the transmission rotating shaft 19 to rotate, the transmission rotating shaft 19 rotates to drive the rotating cylinder 20 to rotate and drive the functional drill bit 54 to rotate, the lifting motor 15 is started to drive the lifting screw 16 to rotate, the lifting screw 16 drives the lifting plate 21 to move downwards through threaded connection, the effect of enabling the functional drill bit 54 to move downwards while rotating is achieved, the functional drill bit 54 pushes the closing plate 63 to downwards overcome the elasticity of the torsion spring of the supporting rotating shaft 60 to turn downwards in the downward moving process, the functional drill bit 54 moves downwards into a rock layer and breaks the rock layer, and in the process that the lifting plate 21 moves to a lower limit position, the lower end face of the switching block 53 abuts against the end face of the lower wall of the lifting cavity 27 and gradually moves the switching block 53, at the moment, the switching block 53 overcomes the elastic force of the switching spring 52 to move upwards to switch the pull rope 50 without tensioning, at the moment, the connection pull rope 64 connected with the switching pull rope 50 is loosened, at the moment, the supporting lifting block 67 moves downwards due to the elastic force of the connection spring 65 and pushes the movable supporting plate 58 to move downwards gradually, the movable supporting plate 58 moves downwards to drive the communication plate 55 to move downwards, at the moment, the communication cavity 56 is communicated with the left side and the right side of the storage cavity 57, at the moment, the rock drilled and crushed by the downward movement due to the continuous rotation of the functional drill 54 gradually enters the storage cavity 57 to achieve the effect of sampling the rock, at the moment, the lifting motor 15 rotates reversely to start to drive the lifting plate 21 to move upwards, the functional drill 54 does not rotate any more when the lifting plate 21 moves upwards gradually, the lower end face of the switching At this time, the switching block 53 pulls the switching pull rope 50 to tension and pulls the connecting pull rope 64, the connecting pull rope 64 pulls the supporting lifting block 67 to move upwards against the elastic force of the connecting spring 65, the supporting lifting block 67 drives the movable supporting plate 58 and drives the functional drill 54 to return to the initial working position, meanwhile, the functional drill 54 does not abut against the closing plate 63, the closing plate 63 rotates to the initial working position under the elastic force of the torsion spring of the supporting rotating shaft 60, the left end surface and the right end surface of the closing plate 63 abut against each other and are closed, when the functional drill 54 moves back into the rock storage cavity 28 and moves to the upper limit position, the upper end surface of the communication plate 55 abuts against the upper end surface of the rock storage cavity 28, at this time, the communication plate 55 starts to move downwards due to the upper wall of the rock storage cavity 28 and finally enables the left side and the right side of the storage cavity 57 to be communicated, at this time, the functional motor 29 starts to, the moving plate 26 drives the pushing rod 25 to move leftwards and move into the storage cavity 57 to withdraw the rocks collected in the storage cavity 57 leftwards and drop to the lower wall end face of the rock storage cavity 28, at this time, the functional motor 29 is started in a reverse rotation mode to drive the moving plate 26 to move back to an initial working position, meanwhile, the functional motor 29 drives the right power rotating shaft 31 to rotate, the power rotating shaft 31 clockwise rotates through the pawl 42 to clamp the ratchet clamping groove of the inner cavity 37 and drives the ratchet 32 to rotate, the ratchet 32 drives the driving bevel gear 33 to rotate through the connecting rotating shaft 70, the driving bevel gear 33 drives the driven bevel gear 35 to rotate through gear engagement, the driven bevel gear 35 drives the driving pulley 38 to rotate through the rotating shaft 36, the driving pulley 38 drives the driven pulley 47 to rotate through the belt 48, the driven pulley 47 drives the rotating disc 43 to rotate through the rotating shaft 46, and the, the support plate 44 drives the swing rod 45 to swing left and right through sliding connection, at the moment, the swing rod 45 drives the reciprocating plate 40 to reciprocate left and right through hinge connection, at the moment, the reciprocating plate 40 drives the scraper 24 to move in the process of moving to the left limit, the scraper 24 moves to push rock fragments falling from the lower wall in the rock storage cavity 28 to the left in the collection cavity 22 and finally collects the rock fragments in the rock collection box 23 to achieve the effect of mixing the rock fragments of the mobile phone, then, the moving plate 26 moves back to the initial working position, the function motor 29 stops after the reciprocating plate 40 moves back to the initial working position, and the lifting motor 15 drives the lifting plate 21 to move back to the initial working position and then stops.

The invention has the beneficial effects that: the rock fragment recovery device achieves the effect of rock fragment recovery by drilling and sampling the rock, so that the rock exploration sampling efficiency is higher, rock fragments are efficiently recovered by automatically closing and communicating the sampling space of the drill bit, and the rock fragments are uniformly collected after being finally mixed by the effect of multi-point sampling, so that the rock fragment detection of sampling and recovery is closer to actual data, the occurrence of small-probability detection errors is reduced, and the exploration accuracy is greatly improved.

In the above manner, a person skilled in the art can make various changes depending on the operation mode within the scope of the present invention.

Claims (9)

1. A geological exploration equipment that multiple spot rock drilling sample mixes collection, includes the exploration organism, its characterized in that: a lifting cavity is arranged in the exploration machine body, a lifting screw rod is rotatably arranged between the upper wall and the lower wall of the lifting cavity, a lifting plate capable of moving up and down is arranged in the lifting cavity, the central position of the lifting plate is in threaded connection with the lifting screw rod, a rotating cylinder with four mechanisms which are distributed in the lifting cavity in an annular matrix manner is arranged, the rotating cylinders are respectively and rotatably connected with the lifting plate, a transmission rotating shaft is rotatably arranged in each rotating cylinder and is in splined connection with the rotating cylinder, a rock storage cavity is arranged in the lower wall of the lifting cavity, sliding grooves positioned below the rotating cylinders are respectively arranged at the communication positions of the rock storage cavity and the lifting cavity, the rotating cylinders extend downwards into the rock storage cavity and are respectively and fixedly connected with a functional drill bit, and storage cavities penetrating left and right are respectively arranged in the functional drill bit, the functional drill bit is internally provided with communicating plates which are respectively arranged on the left side and the right side of the functional drill bit and can move up and down, a communicating cavity is arranged in each communicating plate, a lifting moving cavity is arranged on the inner side of each storage cavity, the lower end of each communicating plate penetrates through the storage cavity and penetrates through the lifting moving cavity, a moving supporting plate which can move up and down is arranged in each lifting moving cavity, the left end surface and the right end surface of each moving supporting plate are respectively fixedly connected with the communicating plates close to the end surface of one side of the rotary cylinder, the lower wall of each rock storage cavity is respectively arranged below the functional drill bit and is provided with four drilling cavities with downward openings in an annular matrix arrangement mode, a bilateral symmetry overturning and elastic closing plate is arranged in each drilling cavity, a rotating cavity is arranged on one side of the closing plate, which is far away from, support pivot excircle terminal surface be close to symmetrical center side end face respectively with symmetrical center side end face fixed connection is kept away from to the closing plate, the movable plate that intracavity top intermediate position and right side position mechanism are the same respectively and can remove about the rock is deposited, the catch bar that just symmetry around the movable plate left end face was equipped with, the catch bar with storage chamber side face size is the same, the rock is deposited intracavity lower wall and is equipped with the scraper blade that can the horizontal slip.

2. A multi-point rock drilling sample collection mix geological survey apparatus as claimed in claim 1 wherein: the upper end face of the lifting screw rod extends upwards and penetrates through the transmission cavity, a lifting motor is fixedly arranged on the upper portion of the lifting screw rod in the upper wall of the transmission cavity, and the upper end of the lifting screw rod is in power connection with the lifting motor.

3. A multi-point rock drilling sample collection mix geological survey apparatus as claimed in claim 1 wherein: the lifting cavity is internally provided with a transmission cavity in the upper wall, the upper end face of the transmission rotating shaft extends upwards to the transmission cavity and is fixedly connected with a rotating chain wheel, the rotating chain wheels are arranged between the rotating chain wheels in a winding mode, the transmission cavity is internally provided with a left front side, a rotating motor is fixedly arranged above the power shaft, and the power shaft is connected with the rotating motor in a power mode.

4. A multi-point rock drilling sample collection mix geological survey apparatus as claimed in claim 1 wherein: each side it just is located to rotate drum excircle terminal surface left side the lifter plate below is fixed to be equipped with and switches the board, be equipped with the switching chamber that the opening is decurrent in the switching board, it is equipped with the switching piece that can reciprocate to switch the intracavity, switching piece up end fixedly connected with switches the stay cord, switching piece up end with switch fixedly connected with switching spring between the chamber upper wall terminal surface.

5. A multi-point rock drilling sample collection mix geological survey apparatus as claimed in claim 1 wherein: the lifting moving cavity is characterized in that a connecting cavity is formed in the right side of the upper wall of the lifting moving cavity in a communicating mode, a supporting lifting block capable of moving up and down is arranged in the connecting cavity, the lower end face of the supporting lifting block is fixedly connected with the upper end face of the moving supporting plate, the upper end face of the supporting lifting block is fixedly connected with a connecting spring between the end faces of the upper wall of the connecting cavity, the upper end face of the supporting lifting block is fixedly connected with a connecting spring, and the connecting spring is connected with a switching pull rope.

6. A multi-point rock drilling sample collection mix geological survey apparatus as claimed in claim 1 wherein: the rock is deposited the intracavity and is rotated above between the two walls and be equipped with the removal threaded rod, the movable plate respectively with removal threaded rod threaded connection, the rock is deposited the intracavity right side wall internal fixation and is equipped with the function motor, removal threaded rod right-hand member power connect in the function motor.

7. A multi-point rock drilling sample collection geological survey apparatus as defined in claim 6 wherein: the utility model discloses a reciprocating rock collection device, including reciprocating plate, scraper blade, reciprocating plate, oscillating bar, reciprocating chamber front wall, reciprocating chamber back wall, rotation pivot excircle terminal surface fixedly connected with rotating disc, rotating disc back end hinged joint has the backup pad, sliding connection has the swinging arms in the backup pad, terminal surface under the swinging arms with reciprocating plate up end hinged joint.

8. A multi-point rock drilling sample collection geological survey apparatus as claimed in claim 7 wherein: just be located in the reciprocating cavity antetheca it is equipped with the band pulley chamber of below slope to rotate disc the place ahead, rotate the pivot preceding terminal surface and extend forward to band pulley intracavity fixedly connected with driven pulleys, band pulley intracavity lower wall rotates and is equipped with driving pulley, driving pulley with around being equipped with the belt between the driven pulleys, driving pulley rear end face axle center fixedly connected with transmission shaft.

9. A multi-point rock drilling sample collection geological survey apparatus as defined in claim 8 wherein: a gear cavity is arranged in the rear wall of the belt wheel cavity, the transmission shaft extends backwards into the gear cavity and is fixedly connected with a driven bevel gear, a driving bevel gear meshed with the driven bevel gear is arranged on the left wall in the gear cavity in a rotating manner, the axis of the left end face of the driving bevel gear is fixedly connected with a connecting rotating shaft, a ratchet cavity is arranged in the left wall of the gear cavity and is positioned on the right side of the functional motor, the left end face of the connecting rotating shaft extends leftwards into the ratchet cavity and is fixedly connected with a ratchet wheel, an inner circular cavity with a leftward opening is arranged in the ratchet wheel, a ratchet wheel clamping groove is arranged on the inner circular surface in the inner circular cavity, a power rotating shaft is arranged on the left wall in the ratchet wheel cavity in a rotating manner, the right end of the power rotating shaft extends into the inner circular cavity, pawls which are bilaterally symmetrical are respectively arranged on the outer, when the pawl rotates anticlockwise, the pawl is not clamped with the inner cavity clamping groove.

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