CN114184423A - Geological survey sampling system - Google Patents

Abstract

The invention discloses a geological exploration sampling system which comprises a collecting shell, wherein a sealing cover is detachably mounted on the upper surface of the collecting shell, through holes are formed in two sides of the collecting shell, a first shaft is fixedly and axially connected through the two through holes, a first gear is fixedly sleeved on an arc-shaped outline extending out of one end of the collecting shell on the first shaft, a second gear is meshed with teeth on the first gear in a transmission manner, a second shaft is fixedly connected to the inner wall of the second gear, one end of the second shaft is coaxially and fixedly connected with a first rotating wheel, the other end of the second shaft penetrates through the collecting shell and is axially rotated on the collecting shell, and second rotating wheels matched with the first rotating wheels are rotatably connected to the fixed shafts on the two sides of the collecting shell. According to the invention, through the matching use of the structures, the problems that in the actual use process, as the traditional soil sample sampling is mostly manually carried out, the sampling process is interfered by random factors, the sampling result is not accurate enough, and the use is inconvenient are solved.

Description

Geological survey sampling system

Technical Field

The invention relates to the technical field of geological exploration sampling equipment, in particular to a geological exploration sampling system.

Background

The geological exploration can be understood as geological work in a broad sense, and is the investigation and research work on geological conditions such as rocks, stratum structures, mineral products, underground water, landforms and the like in a certain area by applying geological exploration methods such as mapping, geophysical exploration, geochemical prospecting, drilling, pit exploration, sampling test, geological remote sensing and the like according to the needs of economic construction, national defense construction and scientific and technical development.

Wherein need take a sample to earth's surface soil in geological survey, traditional soil sample is the manual sampling operation that carries out more, and there is random factor's interference in the sampling process, causes the sampling result accurate inadequately, brings the inconvenience for the use.

Disclosure of Invention

The invention aims to provide a geological survey sampling system which has the advantages of automatic sampling, auxiliary sampling, multi-point sampling and centralized collection and solves the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: the utility model provides a geological survey sampling system, is including collecting the shell, it has sealed lid to collect shell upper surface demountable installation, the both sides of collecting the shell are seted up the through-hole and are rotated through these two through-hole dead axles and be connected with axle one, the fixed cover has gear one on the arc profile that stretches out collection shell one end on the axle one, the tooth transmission meshing on the gear one has gear two, gear two's inner wall fixedly connected with axle two, the one end of axle two is coaxial to be linked firmly rotates wheel one, the other end of axle two runs through collects the shell and dead axle rotates on collecting the shell, the both sides dead axle of collecting the shell rotate be connected with rotate wheel one complex and rotate wheel two.

The inner wall of the collecting shell is fixedly connected with a third shaft which is driven by a power mechanism to rotate in a fixed-shaft mode, the surfaces, close to the two ends, of the third shaft are respectively sleeved with a first swing arm in a penetrating mode, the bottom of the first swing arm is provided with a groove and is connected with a second swing arm in a rotating mode through the groove in a fixed-shaft mode, the inner wall of the collecting shell is fixedly connected with two symmetrical limiting frames, the inner wall of each limiting frame is connected with a lifting block in a vertically limiting sliding mode, the top of the lifting block is provided with a groove and is connected with the surface, close to the bottom, of the second swing arm in a fixed-shaft mode through the groove, the bottom of the lifting block is fixedly connected with a lifting insertion rod, a third pressure spring is sleeved on the lifting insertion rod, the top of the third pressure spring is fixedly connected with the bottom of the lifting block, the bottom of the third pressure spring is fixedly connected with the bottom of the inner wall of the limiting frame, a sampling system is arranged on the surface, close to the bottom, and a through groove for the sampling system to vertically penetrate through is formed in the lower surface of the collecting shell, the surface of the third shaft close to the two ends is fixedly sleeved with a connecting ring, a third swing arm and a fourth swing arm which are symmetrically arranged are fixedly connected to the arc-shaped outline of the connecting ring, and a shifting lever for shifting the second swing arm is fixedly connected to one side of the third swing arm and one side of the fourth swing arm close to the inner wall of the collecting shell.

Preferably, the sampling system includes the triangular prism shape casing, the upper surface that is close to the rear side on the triangular prism shape casing is run through by the lift inserted bar and with lift inserted bar spacing sliding connection from top to bottom, the bottom fixedly connected with diaphragm of lift inserted bar, the direction slide bar of two symmetries of lower fixed surface of diaphragm and slant, the through-hole has all been seted up and has two horizontal picture pegs, two through the spacing sliding connection of through-hole to the both sides of triangular prism shape casing the upper surface of horizontal picture peg set up with correspond the oblique through-hole of direction slide bar looks adaptation and through this oblique through-hole with correspond the sliding connection in surface of direction slide bar, two the opposite side fixedly connected with pressure spring one of horizontal picture peg.

Preferably, the lifting block is provided with an auxiliary device for pre-excavating treatment of soil, the auxiliary device comprises two symmetrical transmission rods fixedly connected with the surface of the lifting block, one ends of the two transmission rods far away from the lifting block are fixedly connected with lifting plates, the upper surfaces of the two lifting plates are provided with through holes and are respectively connected with a screw rod I and a screw rod II in a limiting rotation manner through the through holes, the bottoms of the screw rod I and the screw rod II are respectively and fixedly connected with transmission columns, the inner wall of the collecting shell is fixedly connected with a limiting inserted rod, one end of the limiting inserted rod far away from the inner wall of the collecting shell is fixedly connected with a limiting sleeve, the inner wall of the limiting sleeve is movably connected with the arc-shaped contour surface corresponding to the screw rod I or the screw rod II, one end of the limiting inserted rod far away from the inner wall of the collecting shell penetrates through the limiting sleeve and extends into the limiting sleeve and is connected with the inner wall of the outer contour sliding chute on the screw rod I or the screw rod II in a sliding manner, the bottom of transmission post runs through the lower surface of collecting the shell and fixedly connected with connecting plate, the one end fixedly connected with spiral rotary tillage arm of keeping away from the transmission post on the connecting plate.

Preferably, be equipped with intermittent type drive on the screw rod two and rotate a pivoted transmission, transmission is including seting up the rectangle spacing groove on two tops of screw rod, the screw rod two-way rectangle spacing groove axial sliding connection on it has the rectangular pole, the bottom fixedly connected with pressure spring two of rectangular pole, the bottom of pressure spring two and the bottom fixed connection of rectangle spacing inslot wall on the screw rod two, the fixed surface that is close to the top on the rectangular pole overlaps and has conical gear one, the transmission of the surperficial intermittent type formula meshing of conical gear one is connected with conical gear two, the epaxial surface of keeping away from one end of gear runs through collect the shell and with conical gear two's inner wall fixed connection.

Preferably, the one end that is close to the collection shell on the second axle runs through and collects the shell and coaxial the linking firmly fourth axle, fixedly connected with elasticity plectrum on the arc profile of fourth axle, the last one end fixedly connected with who keeps away from fourth axle of elasticity plectrum dials the flexible friction pad of getting to horizontal picture peg upper surface soil sample.

Preferably, the lower surface of the collecting shell is provided with a falling hole, and the lower surface of the collecting shell, which is just opposite to the falling hole, is fixedly connected with a collecting box for intensively collecting soil samples picked by the elastic shifting piece.

Preferably, the arc-shaped profile of the third shaft is fixedly connected with two symmetrical elastic toggle arms, the two elastic toggle arms abut against the corresponding toggle rod, and the opposite sides of the two elastic toggle arms close to the bottom are fixedly connected with the toggle plates.

Preferably, the bottom of the guide sliding rod is fixedly connected with a cushion block, and the lower surface of the cushion block is movably connected with the inner wall of the triangular prism-shaped shell.

Compared with the prior art, the invention has the following beneficial effects: the invention realizes the protection of the whole device through the collecting shell; the sealing cover is detached, so that the sample soil collected in the collection shell can be taken out;

the first gear is driven to rotate through the shaft, the second gear meshed with the first gear drives the second upper shaft to rotate, the first rotating wheel is finally driven to rotate, and under the rotating fit of the second rotating wheel, the whole collecting shell device is finally moved on a soil layer to be sampled.

The power mechanism is a motor after being connected with a power supply, and an output shaft of the motor drives the third shaft to rotate in a reciprocating manner;

the connecting ring, the third swing arm and the fourth swing arm on the third shaft synchronously reciprocate at any time, and the two driving levers can synchronously swing through the driving levers on the third swing arm and the fourth swing arm.

The first swing arm can swing in a reciprocating mode with the third shaft as a rotating center through the reciprocating synchronous swinging of the two shift levers, when the first swing arm is rotated to the vertical state from the inclined state, the second swing arm can rotate in a step-by-step adaptive mode to tend to the vertical state, and at the moment, the lifting block can overcome the elastic force of the third pressure spring to drive the lifting inserted link and the sampling system on the lifting inserted link to synchronously move downwards; the lifting block is limited by the frame body structure of the limiting frame and can only slide up and down in the limiting frame.

When the first swing arm, the second swing arm and the lifting block are positioned at the same vertical straight line in the vertical direction, the lifting inserted rod drives the sampling system to descend to the lowest position, and the sampling system positioned at the lowest position is completely immersed into soil to be sampled;

simultaneously when swing arm one, swing arm two, the elevator three is in same vertical straight line department in vertical direction, swing arm one, swing arm two and elevator three then are in under balanced state, but in case continue to realize shifting to swing arm one through the driving lever, then can break above-mentioned balance, under the effect of the elasticity on the pressure spring three, can make the elevator shift up fast, the lift inserted bar and the sampling system of elevator bottom then can shift up with step-by-step, move up in-process sampling system can be with the soil of collecting on it together bring up.

Therefore, the soil sampling operation is completed, and the whole device can realize dynamic sampling along with the whole movable operation of the device.

Through the setting of auxiliary device, can carry out the preliminary treatment to the soil that the sampling system will excavate, make the soil in this region can be excavated more easily.

Through transmission's setting, can carry out adaptability collaborative operation with excavating and collecting the holistic removal of shell, collect the shell promptly when static, can realize the sample operation to soil, and when collecting the shell and remove, make the contact that sampling system breaks away from with soil for remove and sample and excavate and can not mutual interference.

Through the cooperation use between the above-mentioned structure, solved in the in-service use process, because traditional soil sample is many for manual sampling operation, there is random factor's interference in the sampling process, causes the sampling result accurate inadequately, gives the problem of inconvenience of using.

Drawings

FIG. 1 is a perspective view of a collection housing of the present invention;

FIG. 2 is a perspective view of a sampling system of the present invention;

FIG. 3 is a perspective view of the elevator block of the present invention;

FIG. 4 is a side cross-sectional view of a triangular prism-shaped housing of the present invention;

FIG. 5 is a perspective view of a first swing arm of the present invention;

FIG. 6 is a perspective view of a helical rotary tillage arm of the present invention;

FIG. 7 is a front cross-sectional view of a second screw of the present invention;

fig. 8 is a perspective view of a shaft four of the present invention.

In the figure: 1. collecting the shells; 2. a sealing cover; 3. a first shaft; 4. a first gear; 5. a second gear; 6. a second shaft; 7. rotating the first wheel; 8. a second rotating wheel; 9. a third shaft; 10. a first swing arm; 11. a second swing arm; 12. a limiting frame; 13. a lifting block; 14. a lifting inserted rod; 15. a third pressure spring; 16. a sampling system; 17. a connecting ring; 18. a third swing arm; 19. a fourth swing arm; 20. a deflector rod; 21. a triangular prism-shaped housing; 22. a transverse plate; 23. a guide slide bar; 24. a horizontal plug board; 25. a first pressure spring; 26. a transmission rod; 27. a lifting plate; 28. a first screw rod; 29. a second screw; 30. a drive post; 31. a limiting inserted rod; 32. a limiting sleeve; 301. a connecting plate; 302. a spiral rotary tillage arm; 33. a rectangular bar; 34. a second pressure spring; 35. a first conical gear; 36. a second bevel gear; 37. shaft four; 38. an elastic shifting piece; 39. a flexible friction pad; 40. dropping a hole; 41. a collection box; 42. an elastic poking arm; 43. a poking plate; 44. and a cushion block.

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. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The first embodiment is as follows:

the invention provides a technical scheme that: a geological exploration sampling system comprises a collecting shell 1, the whole device is protected by the collecting shell 1, a sealing cover 2 is detachably arranged on the upper surface of the collecting shell 1, the collected sample soil in the collecting shell 1 can be taken out by detaching the sealing cover 2, through holes are formed in two sides of the collecting shell 1, a first shaft 3 is fixedly connected with the two through holes in a fixed-shaft rotating mode, a first gear 4 is fixedly sleeved on an arc-shaped outline, extending out of one end of the collecting shell 1, of the first shaft 3, a second gear 5 is meshed with the first gear 4 in a gear transmission mode, a second shaft 6 is fixedly connected to the inner wall of the second gear 5, one end of the second shaft 6 is fixedly connected with a first rotating wheel 7 in a coaxial mode, the other end of the second shaft 6 penetrates through the collecting shell 1 and rotates on the collecting shell 1 in a fixed-shaft rotating mode, second rotating wheels 8 matched with the first rotating wheels 7 are rotatably connected with the two sides of the collecting shell 1 in a fixed-shaft rotating mode, the first gear 4 is driven to rotate through the first shaft 3, and a second gear 5 meshed with the first gear 4 drives a second upper shaft 6 to rotate, finally drives a first rotating wheel 7 to rotate, and finally realizes the movement of the whole collecting shell 1 device on a soil layer to be sampled under the rotation matching of a second rotating wheel 8.

The inner wall of the collecting shell 1 is fixedly connected with a shaft III 9 which is driven to rotate by a power mechanism in a fixed-shaft rotating mode, the shaft III 9 is driven to rotate in a reciprocating mode through the power mechanism, the power mechanism is a motor after being connected with a power supply, and an output shaft of the motor drives the shaft III 9 to rotate in a reciprocating mode.

The surface of the third shaft 9 close to the two ends is sleeved with a first swing arm 10 in a penetrating way, the bottom of the first swing arm 10 is provided with a groove and is connected with a second swing arm 11 through the groove in a fixed-axis rotating way, the inner wall of the collecting shell 1 is fixedly connected with two symmetrical limiting frames 12, the inner wall of the limiting frames 12 is connected with a lifting block 13 in a limiting and sliding way, the top of the lifting block 13 is provided with a groove and is connected with the surface of the second swing arm 11 close to the bottom through the groove in a fixed-axis rotating way, the bottom of the lifting block 13 is fixedly connected with a lifting inserted rod 14, the lifting inserted rod 14 is sleeved with a third pressure spring 15, the top of the third pressure spring 15 is fixedly connected with the bottom of the lifting block 13, the bottom of the third pressure spring 15 is fixedly connected with the bottom of the inner wall of the limiting frame 12, the surface of the lifting inserted rod 14 close to the bottom is provided with a sampling system 16, the lower surface of the collecting shell 1 is provided with a through groove for the sampling system 16 to pass through the reciprocating synchronous swinging of the two driving levers 20 below, the reciprocating swing of the swing arm I10 by taking the shaft III 9 as a rotation center can be realized, when the swing arm I10 is rotated to a vertical state from an inclined state, the swing arm II 11 can adaptively rotate step by step and tends to the vertical state, and at the moment, the lifting block 13 can overcome the elastic force of the pressure spring III 15 to drive the lifting inserted rod 14 and the sampling system 16 on the lifting inserted rod 14 to synchronously move downwards; the lifting block 13 is limited by the frame structure of the limit frame 12, and can only slide in the limit frame up and down.

The equal fixed cover in surface that is close to both ends has go-between 17 on the three 9 of axle, swing arm three 18 and swing arm four 19 that fixedly connected with symmetry set up on the arc profile of go-between 17, the equal fixedly connected with in one side that is close to collection shell 1 inner wall on swing arm three 18 and the swing arm four 19 is used for stirring the driving lever 20 of swing arm two 11, go-between 17 on the three 9 of axle, swing arm three 18 and swing arm four 19 reciprocate the rotation at any time in step, through the setting of driving lever 20 on swing arm three 18 and the swing arm four 19, make these two driving levers 20 can swing in step.

When the first swing arm 10, the second swing arm 11 and the lifting block 13 are in the same vertical straight line in the vertical direction, the lifting inserted rod 14 drives the sampling system 16 to descend to the lowest position, and the sampling system 16 at the lowest position is completely immersed into soil to be sampled.

Meanwhile, when the first swing arm 10, the second swing arm 11 and the lifting block 13 are positioned on the same vertical straight line in the vertical direction, the first swing arm 10, the second swing arm 11 and the lifting block 13 are in a balance state, but once the first swing arm 10 is continuously shifted through the shifting rod 20, the balance can be broken, the lifting block 13 can quickly move upwards under the action of elastic force of the pressure spring three 15, the lifting inserted rod 14 at the bottom of the lifting block 13 and the sampling system 16 can move upwards simultaneously, and the sampling system 16 can carry the soil collected on the lifting inserted rod together in the upwards moving process.

Therefore, the soil sampling operation is completed, and the whole device can realize dynamic sampling along with the whole movable operation of the device.

Further, sampling system 16 includes triangular prism shape casing 21, the upper surface that is close to the rear side on triangular prism shape casing 21 is run through by lift inserted bar 14 and with lift inserted bar 14 spacing sliding connection from top to bottom, the bottom fixedly connected with diaphragm 22 of lift inserted bar 14, the lower fixed surface of diaphragm 22 is connected with two symmetry and oblique guide slide bar 23, the through-hole has all been seted up to triangular prism shape casing 21's both sides and has two horizontal picture peg 24 through the spacing sliding connection of through-hole, the oblique through-hole of two horizontal picture pegs 24 with corresponding guide slide bar 23 looks adaptations is seted up and is connected with the surface sliding who corresponds guide slide bar 23 through this oblique through-hole, the opposite side fixedly connected with pressure spring 25 of two horizontal picture pegs 24.

Referring to fig. 4, along with the downward movement of the lifting insertion rod 14, the horizontal plate 22 and the guide slide rod 23 move downward synchronously, and under the guidance of the inclined direction of the body of the guide slide rod 23, the two horizontal insertion plates 24 move oppositely after overcoming the elasticity of the first compression spring 25, so that the two horizontal insertion plates 24 are retracted into the triangular prism-shaped shell 21, and the triangular prism-shaped shell 21 is conveniently and integrally inserted into the soil layer.

The tip of the whole triangular prism-shaped shell 21 faces downwards, so that the triangular prism-shaped shell 21 can enter a soil layer more easily, when the lifting inserted bar 14 is pulled to move upwards, under the transmission of the transverse plate 22 and the influence of the gravity of the triangular prism-shaped shell 21, the two guide slide bars 23 smoothly move upwards in the triangular prism-shaped shell 21, under the guide of the inclined direction of the body of the guide slide bars 23 and the action of the elastic force of the first compression spring 25, the two horizontal inserted plates 24 simultaneously move away from each other, namely, the horizontal inserted plates 24 gradually extend out of the triangular prism-shaped shell 21, the extending parts of the horizontal inserted plates 24 are inserted into the soil layer, and along with the upward movement of the whole triangular prism-shaped shell 21, the horizontal inserted plates 24 synchronously move upwards, and in the upward movement process, soil in a target soil layer can be excavated and lifted upwards;

thereby completing the sampling operation of the soil layer in the target area.

Example two

Basically the same as the first embodiment, further: the lifting block 13 is provided with an auxiliary device for pre-excavating the soil, and the soil to be excavated by the sampling system 16 can be pre-treated by the auxiliary device, so that the soil in the area can be excavated more easily.

The auxiliary device comprises two symmetrical transmission rods 26 fixedly connected with the surface of the lifting block 13, wherein the ends of the two transmission rods 26 far away from the lifting block 13 are fixedly connected with lifting plates 27, the upper surfaces of the two lifting plates 27 are provided with through holes, and are respectively connected with a screw rod I28 and a screw rod II 29 in a limiting and rotating manner through the through holes, the bottoms of the screw rod I28 and the screw rod II 29 are fixedly connected with transmission columns 30, the inner wall of the collection shell 1 is fixedly connected with a limiting inserted rod 31, the end of the limiting inserted rod 31 far away from the inner wall of the collection shell 1 is fixedly connected with a limiting sleeve 32, the inner wall of the limiting sleeve 32 is movably connected with the arc-shaped profile surface of the corresponding screw rod I28 or screw rod II 29, the end of the limiting inserted rod 31 far away from the inner wall of the collection shell 1 penetrates into the limiting sleeve 32 and is connected with the inner wall of an outer profile chute on the screw rod I28 or screw rod II 29 in a sliding manner, the bottom of the transmission columns 30 penetrates through the lower surface of the collection shell 1 and is fixedly connected with a connecting plate 301, one end of connecting plate 301 far away from transmission column 30 is fixedly connected with spiral rotary tillage arm 302.

Refer to fig. 2 and 3.

When the lifting block 13 is lifted, the lifting plate 27 is lifted synchronously under the driving of the transmission rod 26, and since the lifting plate 27 and the corresponding screw rod one 28 and screw rod two 29 are both in limited rotational connection, that is, the screw rod one 28 and screw rod two 29 can rotate on the corresponding lifting plate 27, and cannot move axially in the vertical direction relative to the lifting plate 27.

Therefore, when the driving rod 26 drives the lifting plate 27 to move downwards, the screw rod one 28 or the screw rod two 29 on the lifting plate 27 synchronously moves downwards along with the lifting plate 27, the limit inserting rod 31 in fig. 2 penetrates through the limit sleeve 32 and extends into the limit sleeve 32, the extending end of the limit inserting rod 31 is arranged in the inner wall of the outer contour sliding groove of the screw rod one 28 and the screw rod two 29, and the screw rod one 28 and the screw rod two 29 can rotate relative to the corresponding lifting plate 27 under the guidance of the outer contour sliding groove of the screw rod one 28 and the screw rod two 29 to realize the downward movement;

through the transmission of transmission post 30 and connecting plate 301 for spiral rotary tillage arm 302 can rotate when the axial moves down, through rotating, can carry out the excavation operation in advance of rotation type with the soil layer in the target area, and the triangular prism shape casing 21 of convenient follow-up whereabouts can be more easy stretches into to the soil layer in, realizes the sample to soil layer in the target area.

In this embodiment, the bottom of triangular prism housing 21 is higher than the upper surface of spiral rotary tillage arm 302 at any time, and the two will not collide or be restricted in movement. And spiral rotary tillage arm 302 is the spiral structure, can realize more efficient excavation operation.

EXAMPLE III

Basically the same as the second embodiment, further: be equipped with intermittent type drive on the screw rod two 29 and rotate wheel 7 pivoted transmission, through transmission's setting, can carry out adaptability collaborative operation with excavating and collecting the holistic removal of shell 1, collect shell 1 promptly when static, can realize the sample operation to soil, and when collecting shell 1 and remove, make sampling system 16 break away from the contact with soil for remove and sample and excavate and can not mutual interference.

The transmission device comprises a rectangular limiting groove formed in the top of the second screw rod 29, the second screw rod 29 is connected with a rectangular rod 33 through the rectangular limiting groove in the second screw rod 29 in an axial sliding mode, the bottom of the rectangular rod 33 is fixedly connected with a second pressure spring 34, the bottom of the second pressure spring 34 is fixedly connected with the bottom of the inner wall of the rectangular limiting groove in the second screw rod 29, a first conical gear 35 is fixedly sleeved on the rectangular rod 33, the surface of the first conical gear 35 is in intermittent meshing transmission connection with a second conical gear 36, and the surface, far away from one end of the first gear 4, of the first shaft 3 penetrates through the collecting shell 1 and is fixedly connected with the inner wall of the second conical gear 36.

Refer to fig. 2 and 3.

When the lifting block 13 moves upwards, the second screw 29 moves upwards synchronously through the transmission of the transmission rod 26 and the lifting plate 27, and the second screw 29 can rotate synchronously when moving upwards under the matching of the limiting inserted rod 31 and the limiting sleeve 32;

the rectangular limiting groove formed in the top of the second screw 29 enables the rectangular rod 33 therein to synchronously rotate along with the second screw 29, and the first conical gear 35 coaxially and fixedly connected with the rectangular rod 33 synchronously rotates along with the rectangular rod.

With the continuous upward movement of the second screw 29, the teeth on the first conical gear 35 are finally contacted with the teeth on the second conical gear 36 to complete the transmission engagement; the second conical gear 36 drives the first shaft 3 to rotate on the collecting shell 1 along with the first conical gear 36, and due to the arrangement of the second pressure spring 34, the first conical gear 35 can still keep continuous contact after being in contact and meshed with the second conical gear 36 until the second pressure spring 34 cannot be compressed and deformed.

As can be seen from the foregoing, the movement of the entire collecting case 1 can be realized by the cooperation of the first gear 4, the second gear 5, the second shaft 6, the first rotating wheel 7 and the second rotating wheel 8.

As can be seen from the foregoing, when the lifting block 13 moves downward, the digging and sampling operations can be performed; when the lifting block 13 moves upwards, the digging operation is not carried out any more, and after the second screw 29 moves upwards for a period of time, the first bevel gear 35 on the lifting block and the second bevel gear 36 carry out tooth meshing transmission, so that the spiral rotary tillage arm 302, the triangular prism-shaped shell 21 and other structures can be moved upwards and taken out of the soil layer.

And the clearance of digging is utilized, the movement of the whole device of the collecting shell 1 is realized, namely the sampling operation and the moving operation are accurately matched in a cross way.

Example four

Basically the same as the third embodiment, and further: one end of the second shaft 6, which is close to the collection shell 1, penetrates through the collection shell 1 and is coaxially fixedly connected with a fourth shaft 37, an elastic shifting piece 38 is fixedly connected to the arc-shaped outline of the fourth shaft 37, and one end of the elastic shifting piece 38, which is far away from the fourth shaft 37, is fixedly connected with a flexible friction pad 39 for shifting soil samples on the upper surface of the horizontal inserting plate 24.

Refer to fig. 3.

With the upward movement of the triangular prism housing 21, the two horizontal insertion plates 24 also protrude from the triangular prism housing 21; at this time, excavation sampling operation is not carried out; as can be seen from the foregoing description, at this time, the collection shell 1 is integrally moved along with the rotation of the second shaft 6, the fourth shaft 37 coaxially and fixedly connected to the second shaft 6 drives the elastic shifting piece 38 and the flexible friction pad 39 to synchronously rotate, the elastic shifting piece 38 itself has elasticity, and can be deformed to complete continuous operation when the rotation is limited by an obstacle, and the flexible friction pad 39 is disposed to contact with the upper surface of the horizontal insertion plate 24 and flicks the sample collected on the upper surface of the horizontal insertion plate 24 to the bottom of the inner wall of the collection shell 1, so as to realize the centralized collection of the sample in the collection shell 1.

Furthermore, a falling hole 40 is formed in the lower surface of the collecting shell 1, and a collecting box 41 for collecting the soil sample collected by the elastic shifting piece 38 is fixedly connected to the lower surface of the collecting shell 1, which is opposite to the falling hole 40.

Refer to fig. 1 and 2.

Through the opening of the falling hole 40, the sample on the bottom of the inner wall of the collecting shell 1 can enter the collecting box 41 by stirring, and further concentrated collection is achieved, and the specific stirring operation is disclosed and explained hereinafter.

Furthermore, two symmetrical elastic toggle arms 42 are fixedly connected to the arc-shaped profile of the third shaft 9, the two elastic toggle arms 42 abut against the corresponding toggle lever 20, and toggle plates 43 are fixedly connected to the opposite sides of the two elastic toggle arms 42 close to the bottom.

Referring to fig. 2, by the arrangement of two elastic poking arms 42 on the arc profile of the third shaft 9 and the arrangement of the poking plate 43 on the elastic poking arms 42, the sample falling on the bottom of the inner wall of the collecting shell 1 can be poked to be promoted to fall into the collecting box 41 for further collection.

Further, the bottom of the guide sliding rod 23 is fixedly connected with a cushion block 44, and the lower surface of the cushion block 44 is movably connected with the inner wall of the triangular prism-shaped shell 21.

The stability of the guide slide bar 23 in use can be improved by the provision of the spacer 44.

The working principle is as follows: when the geological exploration sampling system is used, the whole device is protected through the collecting shell 1; the sealing cover 2 is detached, so that the sample soil collected in the collecting shell 1 can be taken out;

the first gear 4 is driven to rotate through the first shaft 3, the second gear 5 meshed with the first gear 4 drives the second upper shaft 6 to rotate, the first rotating wheel 7 is finally driven to rotate, and the whole collecting shell 1 device is finally moved on a soil layer to be sampled under the rotation matching of the second rotating wheel 8.

The power mechanism drives the shaft III 9 to rotate in a reciprocating manner, the power mechanism is a motor after being connected with a power supply, and an output shaft of the motor drives the shaft III 9 to rotate in a reciprocating manner;

the connecting ring 17, the swing arm III 18 and the swing arm IV 19 on the shaft III 9 synchronously reciprocate at any time, and the two shift levers 20 can synchronously swing through the arrangement of the shift levers 20 on the swing arm III 18 and the swing arm IV 19.

The reciprocating synchronous swing of the first swing arm 10 by taking the third shaft 9 as a rotation center can be realized through the reciprocating synchronous swing of the two shift levers 20, when the first swing arm 10 is rotated to a vertical state from an inclined state, the second swing arm 11 can adaptively rotate with the first shaft to tend to the vertical state, and at the moment, the lifting block 13 can overcome the elastic force of the third pressure spring 15 to drive the lifting inserted link 14 and the sampling system 16 on the lifting inserted link 14 to synchronously move downwards; the lifting block 13 is limited by the frame structure of the limit frame 12, and can only slide in the limit frame up and down.

When the first swing arm 10, the second swing arm 11 and the lifting block 13 are positioned at the same vertical straight line in the vertical direction, the lifting inserted rod 14 drives the sampling system 16 to descend to the lowest position, and the sampling system 16 positioned at the lowest position is completely immersed into soil to be sampled;

meanwhile, when the first swing arm 10, the second swing arm 11 and the lifting block 13 are positioned on the same vertical straight line in the vertical direction, the first swing arm 10, the second swing arm 11 and the lifting block 13 are in a balance state, but once the first swing arm 10 is continuously shifted through the shifting rod 20, the balance can be broken, the lifting block 13 can quickly move upwards under the action of elastic force of the pressure spring three 15, the lifting inserted rod 14 at the bottom of the lifting block 13 and the sampling system 16 can move upwards simultaneously, and the sampling system 16 can carry the soil collected on the lifting inserted rod together in the upwards moving process.

Referring to fig. 4, along with the downward movement of the lifting insertion rod 14, the horizontal plate 22 and the guide slide rod 23 move downward synchronously, and under the guidance of the inclined direction of the body of the guide slide rod 23, the two horizontal insertion plates 24 move oppositely after overcoming the elasticity of the first compression spring 25, so that the two horizontal insertion plates 24 are retracted into the triangular prism-shaped shell 21, and the triangular prism-shaped shell 21 is conveniently and integrally inserted into the soil layer.

The tip of the whole triangular prism-shaped shell 21 faces downwards, so that the triangular prism-shaped shell 21 can enter a soil layer more easily, when the lifting inserted bar 14 is pulled to move upwards, under the transmission of the transverse plate 22 and the influence of the gravity of the triangular prism-shaped shell 21, the two guide slide bars 23 smoothly move upwards in the triangular prism-shaped shell 21, under the guide of the inclined direction of the body of the guide slide bars 23 and the action of the elastic force of the first compression spring 25, the two horizontal inserted plates 24 simultaneously move away from each other, namely, the horizontal inserted plates 24 gradually extend out of the triangular prism-shaped shell 21, the extending parts of the horizontal inserted plates 24 are inserted into the soil layer, and along with the upward movement of the whole triangular prism-shaped shell 21, the horizontal inserted plates 24 synchronously move upwards, and in the upward movement process, soil in a target soil layer can be excavated and lifted upwards;

thereby completing the sampling operation of the soil layer in the target area.

Therefore, the soil sampling operation is completed, and the whole device can realize dynamic sampling along with the whole movable operation of the device.

By providing the auxiliary device, the soil to be excavated by the sampling system 16 can be pre-treated, so that the soil in the area can be excavated more easily.

Refer to fig. 2 and 3.

When the lifting block 13 is lifted, the lifting plate 27 is lifted synchronously under the driving of the transmission rod 26, and since the lifting plate 27 and the corresponding screw rod one 28 and screw rod two 29 are both in limited rotational connection, that is, the screw rod one 28 and screw rod two 29 can rotate on the corresponding lifting plate 27, and cannot move axially in the vertical direction relative to the lifting plate 27.

Therefore, when the driving rod 26 drives the lifting plate 27 to move downwards, the screw rod one 28 or the screw rod two 29 on the lifting plate 27 synchronously moves downwards along with the lifting plate 27, the limit inserting rod 31 in fig. 2 penetrates through the limit sleeve 32 and extends into the limit sleeve 32, the extending end of the limit inserting rod 31 is arranged in the inner wall of the outer contour sliding groove of the screw rod one 28 and the screw rod two 29, and the screw rod one 28 and the screw rod two 29 can rotate relative to the corresponding lifting plate 27 under the guidance of the outer contour sliding groove of the screw rod one 28 and the screw rod two 29 to realize the downward movement;

through the transmission of transmission post 30 and connecting plate 301 for spiral rotary tillage arm 302 can rotate when the axial moves down, through rotating, can carry out the excavation operation in advance of rotation type with the soil layer in the target area, and the triangular prism shape casing 21 of convenient follow-up whereabouts can be more easy stretches into to the soil layer in, realizes the sample to soil layer in the target area.

In this embodiment, the bottom of triangular prism housing 21 is higher than the upper surface of spiral rotary tillage arm 302 at any time, and the two will not collide or be restricted in movement. And spiral rotary tillage arm 302 is the spiral structure, can realize more efficient excavation operation.

Through transmission's setting, can carry out adaptability collaborative operation with excavating and collecting the holistic removal of shell 1, collect shell 1 promptly when static, can realize the sample operation to soil, and when collecting shell 1 and remove, make sampling system 16 break away from the contact with soil for remove and sample and excavate and can not mutual interference.

Refer to fig. 2 and 3.

When the lifting block 13 moves upwards, the second screw 29 moves upwards synchronously through the transmission of the transmission rod 26 and the lifting plate 27, and the second screw 29 can rotate synchronously when moving upwards under the matching of the limiting inserted rod 31 and the limiting sleeve 32;

the rectangular limiting groove formed in the top of the second screw 29 enables the rectangular rod 33 therein to synchronously rotate along with the second screw 29, and the first conical gear 35 coaxially and fixedly connected with the rectangular rod 33 synchronously rotates along with the rectangular rod.

With the continuous upward movement of the second screw 29, the teeth on the first conical gear 35 are finally contacted with the teeth on the second conical gear 36 to complete the transmission engagement; the second conical gear 36 drives the first shaft 3 to rotate on the collecting shell 1 along with the first conical gear 36, and due to the arrangement of the second pressure spring 34, the first conical gear 35 can still keep continuous contact after being in contact and meshed with the second conical gear 36 until the second pressure spring 34 cannot be compressed and deformed.

As can be seen from the foregoing, the movement of the entire collecting case 1 can be realized by the cooperation of the first gear 4, the second gear 5, the second shaft 6, the first rotating wheel 7 and the second rotating wheel 8.

As can be seen from the foregoing, when the lifting block 13 moves downward, the digging and sampling operations can be performed; when the lifting block 13 moves upwards, the digging operation is not carried out any more, and after the second screw 29 moves upwards for a period of time, the first bevel gear 35 on the lifting block and the second bevel gear 36 carry out tooth meshing transmission, so that the spiral rotary tillage arm 302, the triangular prism-shaped shell 21 and other structures can be moved upwards and taken out of the soil layer.

And the clearance of digging is utilized, the movement of the whole device of the collecting shell 1 is realized, namely the sampling operation and the moving operation are accurately matched in a cross way.

Through the cooperation use between the above-mentioned structure, solved in the in-service use process, because traditional soil sample is many for manual sampling operation, there is random factor's interference in the sampling process, causes the sampling result accurate inadequately, gives the problem of inconvenience of using.

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

Claims (8)

1. A geological survey sampling system which characterized in that: including collecting shell (1), it has sealed lid (2) to collect shell (1) upper surface demountable installation, the both sides of collecting shell (1) have been seted up the through-hole and have been rotated through these two through-hole dead axles and be connected with axle one (3), it has gear one (4) to stretch out fixed the cover on the arc profile of collecting shell (1) one end on axle one (3), the tooth transmission meshing on gear one (4) has gear two (5), the inner wall fixedly connected with axle two (6) of gear two (5), the one end of axle two (6) is coaxial to be linked firmly rotates wheel one (7), the other end of axle two (6) runs through collects shell (1) and dead axle rotates on collecting shell (1), the both sides dead axle of collecting shell (1) is rotated and is connected with and rotates wheel one (7) complex and rotates wheel two (8).

2. The geological survey sampling system of claim 1, wherein:

the inner wall fixed shaft of the collecting shell (1) is rotatably connected with a third shaft (9) which is driven by a power mechanism to rotate, the surfaces of the third shaft (9) close to two ends are respectively sleeved with a first swing arm (10) in a penetrating way, the bottom of the first swing arm (10) is provided with a groove and is rotatably connected with a second swing arm (11) through the groove fixed shaft, the inner wall of the collecting shell (1) is fixedly connected with two symmetrical limiting frames (12), the upper part and the lower part of the inner wall of each limiting frame (12) are connected with a lifting block (13) in a limiting way, the top of each lifting block (13) is provided with a groove and is rotatably connected with the surface fixed shaft of the second swing arm (11) close to the bottom through the groove, the bottom of each lifting block (13) is fixedly connected with a lifting inserted rod (14), the lifting inserted rod (14) is sleeved with a third pressure spring (15), and the top of the third pressure spring (15) is fixedly connected with the bottom of each lifting block (13), the bottom of the pressure spring III (15) is fixedly connected with the bottom of the inner wall of the limiting frame (12);

the surface that is close to the bottom on lift inserted bar (14) is equipped with sampling system (16), the lower surface of collecting shell (1) is seted up and is supplied the logical groove that runs through from top to bottom of sampling system (16), the equal fixed cover in surface that is close to both ends has go-between (17) on axle three (9), swing arm three (18) and swing arm four (19) that fixedly connected with symmetry set up on the arc profile of go-between (17), equal fixedly connected with in one side that is close to collecting shell (1) inner wall on swing arm three (18) and swing arm four (19) is used for stirring driving lever (20) of swing arm two (11).

3. The geological survey sampling system of claim 2, wherein:

the sampling system (16) comprises a triangular prism-shaped shell (21), the upper surface of the triangular prism-shaped shell (21) close to the rear side is penetrated by a lifting inserted bar (14) and is in up-and-down limit sliding connection with the lifting inserted bar (14), the bottom of the lifting inserted bar (14) is fixedly connected with a transverse plate (22), the lower surface of the transverse plate (22) is fixedly connected with two symmetrical and inclined guide slide bars (23), both sides of the triangular prism-shaped shell (21) are respectively provided with a through hole and are in limit sliding connection with two horizontal inserting plates (24) through the through hole, the upper surfaces of the two horizontal inserting plates (24) are provided with inclined through holes matched with the corresponding guide slide bars (23) and are in surface sliding connection with the corresponding guide slide bars (23) through the inclined through holes, and the opposite sides of the two horizontal inserting plates (24) are fixedly connected with a first pressure spring (25);

the device is characterized in that an auxiliary device for pre-excavating treatment of soil is arranged on the lifting block (13), the auxiliary device comprises two symmetrical transmission rods (26) fixedly connected with the surface of the lifting block (13), lifting plates (27) are fixedly connected with one ends of the two transmission rods (26) far away from the lifting block (13), through holes are formed in the upper surfaces of the two lifting plates (27), a screw rod I (28) and a screw rod II (29) are respectively connected with the through holes in a limiting rotation mode, transmission columns (30) are fixedly connected with the bottoms of the screw rod I (28) and the screw rod II (29), a limiting insertion rod (31) is fixedly connected with the inner wall of the collecting shell (1), a limiting sleeve (32) is fixedly connected with one end of the limiting insertion rod (31) far away from the inner wall of the collecting shell (1), and the inner wall of the limiting sleeve (32) is movably connected with the surface of an arc contour corresponding to the screw rod I (28) or the screw rod II (29), keep away from the one end of collecting shell (1) inner wall on spacing inserted bar (31) and run through extend to in stop collar (32) and with screw rod (28) or screw rod two (29) on the inner wall sliding connection of outline spout, the bottom of transmission post (30) runs through the lower surface and the fixedly connected with connecting plate (301) of collecting shell (1), keep away from one end fixedly connected with spiral rotary tillage arm (302) of transmission post (30) on connecting plate (301).

4. The geological survey sampling system of claim 3, wherein: be equipped with intermittent type drive on screw rod two (29) and rotate round one (7) pivoted transmission, transmission is including seting up the rectangle spacing groove on screw rod two (29) top, screw rod two (29) are connected with rectangle pole (33) through rectangle spacing groove axial sliding on it, the bottom fixedly connected with pressure spring two (34) of rectangle pole (33), the bottom fixed connection of rectangle spacing inslot wall is gone up with screw rod two (29) in the bottom of pressure spring two (34), the fixed surface that is close to the top on rectangle pole (33) overlaps and has conical gear one (35), the transmission of surface intermittent type formula meshing of conical gear one (35) is connected with conical gear two (36), the surface that keeps away from gear one (4) one end on axle one (3) runs through the inner wall fixed connection who collects shell (1) and with conical gear two (36).

5. The geological survey sampling system of claim 3, wherein: one end that is close to on two (6) of axle and collects shell (1) runs through and collects shell (1) and coaxial four (37) of axle that have linked firmly, fixedly connected with elasticity plectrum (38) on the arc profile of four (37) of axle, keep away from one end fixedly connected with of four (37) of axle on elasticity plectrum (38) and dial flexible friction pad (39) that get to horizontal picture peg (24) upper surface soil sample.

6. The geological survey sampling system of claim 5, wherein: the lower surface of the collecting shell (1) is provided with a falling hole (40), and the collecting shell (1) is fixedly connected with a collecting box (41) which is used for intensively collecting soil samples taken by the elastic shifting piece (38) and is just opposite to the lower surface of the falling hole (40).

7. The geological survey sampling system of claim 2, wherein: two symmetrical elastic poking arms (42) are fixedly connected to the arc-shaped profile of the shaft III (9), the two elastic poking arms (42) are abutted to the corresponding poking rods (20), and poking plates (43) are fixedly connected to the opposite sides, close to the bottom, of the two elastic poking arms (42).

8. The geological survey sampling system of claim 3, wherein: the bottom of the guide sliding rod (23) is fixedly connected with a cushion block (44), and the lower surface of the cushion block (44) is movably connected with the inner wall of the triangular prism-shaped shell (21).

Images