CN114563213A - Geological mineral exploration device - Google Patents

Abstract

The invention discloses a geological mineral exploration device which comprises an exploration sampling cylinder, a retractable supporting mechanism and a movable sampling mechanism, wherein one side of the exploration sampling cylinder is connected with a supporting and fixing ring, the retractable supporting mechanism is arranged on one side of the exploration sampling cylinder, the retractable supporting mechanism comprises a fixing supporting plate, the fixing supporting plate is positioned below the exploration sampling cylinder and is connected with the exploration sampling cylinder, one side of the fixing supporting plate, far away from the exploration sampling cylinder, is hinged with a plurality of uniformly distributed folding triangular supporting plates, limiting fixing holes are formed in the plurality of folding triangular supporting plates, and fixing columns are arranged in the limiting fixing holes. According to the invention, the structure of the geological mineral exploration device is optimized and improved, so that the convenience of the geological mineral exploration device in the use process is obviously improved, the labor intensity of transportation and positioning of the geological mineral exploration device in the use process is reduced, and the use stability of the geological mineral exploration device is greatly improved.

Description

Geological mineral exploration device

Technical Field

The invention belongs to the technical field of address mine site investigation devices, and particularly relates to a geological mineral investigation device.

Background

The geological mineral exploration is based on advanced geological science theory, and on the basis of occupying a large amount of field geological observation and collecting and arranging related geological data, the geological survey, physical exploration, pit drilling exploration engineering and other comprehensive geological means and methods are adopted to obtain reliable geological mineral information data.

At present, a common geological mineral exploration device mainly comprises a rack, a driving mechanism, a drill bit and a sampling assembly, and the drill bit is driven by the driving mechanism and the sampling assembly to run to carry out sampling exploration on an area needing to be explored in the using process.

Present geology mineral exploration device structure is comparatively complicated, and the user of being not convenient for carries and transports, and it is relatively poor to use convenience and stability, and especially when the regional topography of geology mineral exploration is complicated, the transportation and the use of geology mineral exploration device are more complicated for intensity of labour who carries out the exploration to geology mineral products is great.

Therefore, in view of the above technical problems, it is necessary to provide a geological mineral exploration apparatus.

Disclosure of Invention

The invention aims to provide a geological mineral exploration device, which solves the problems of poor use convenience and poor stability of the geological mineral exploration device.

In order to achieve the above object, an embodiment of the present invention provides the following technical solutions:

a geological mineral exploration apparatus comprising: the device comprises a prospecting sampling cylinder, a retractable supporting mechanism and a movable sampling mechanism;

one side of the investigation sampling cylinder is connected with a supporting and fixing ring;

the retractable supporting mechanism is arranged on one side of the investigation sampling cylinder and comprises a fixed supporting plate, the fixed supporting plate is positioned below the investigation sampling cylinder and is connected with the investigation sampling cylinder, one side, away from the investigation sampling cylinder, of the fixed supporting plate is hinged with a plurality of uniformly distributed folding triangular supporting plates, a limiting fixing hole is formed in each folding triangular supporting plate, a fixing column is arranged in each limiting fixing hole, a plurality of uniformly distributed limiting cylinders are arranged on the outer side of each fixing column, a contraction spring is arranged in each limiting cylinder, a fixed ground nail is arranged in each contraction spring and is matched with each contraction spring, and a stable supporting mechanism is connected between each folding triangular supporting plate and each supporting fixing ring;

the movable sampling mechanism is arranged in the investigation sampling cylinder and is used for sampling and processing the address mineral products.

Furthermore, one side of the fixing column, which is far away from the investigation sampling cylinder, is hinged with a plurality of crushing conical heads, the mutually matched crushing conical heads of the plurality of crushing conical heads of the accessible form a fixed conical head, so that the folding triangular supporting plate can be supported and fixed conveniently, a plurality of driving control pieces are arranged between the crushing conical heads, the crushing conical heads can be extruded and unfolded under the action of the movement of the driving control pieces, a driving control cavity matched with the driving control pieces is formed in the fixing column, and the driving control cavity is drilled, so that a movement space is provided for the driving control pieces.

Furthermore, one side of the driving control part, which is far away from the crushing conical head, is hinged with a plurality of driving control rods which are uniformly distributed, the driving control part can be controlled to move through the movement of the driving control rods, a plurality of limiting hinge pins are hinged between the driving control rods and the fixing columns, and the limiting hinge pins play a role in supporting and limiting the driving control rods, so that the driving control rods can rotate along the limiting hinge pins under the action of external force.

Furthermore, one end, far away from the driving control part, of the driving control rod is hinged to a movable supporting piece, the movable supporting piece is matched with the fixed ground nail, the driving control rod can be driven and controlled through movement of the movable supporting piece, a return spring is connected between the movable supporting piece and the fixed column, and the movable supporting piece is convenient to contract and reset through the return spring to play a supporting and controlling role.

Further, the stabilizing support mechanism comprises a plurality of stabilizing support rods, a plurality of stabilizing support rods of the accessible play a role in auxiliary support to the investigation sampling cylinder, and are a plurality of hinged supports are hinged between the stabilizing support rods and the folding triangular support plates, the hinged supports play a role in connecting the stabilizing support rods with the folding triangular support plates, the foldable triangular support plates are supported by the stabilizing support rods in a limiting manner, one side, away from the hinged supports, of each stabilizing support rod is provided with a contraction control rod, the contraction control rods are hinged with the supporting fixing rings, and the contraction control rods play a role in connecting the stabilizing support rods and supporting the fixing rings.

Further, the intracavity is accomodate to having dug in the shrink control lever and having taken in with the steady support pole assorted, and the accessible is accomodate the chamber and is played the effect of shrink control to the steady support pole, be connected with supporting spring between steady support pole and the shrink control lever, supporting spring locates and accomodates the intracavity, and supporting spring plays the effect of connecting steady support pole and shrink control lever, and accessible supporting spring's shrink and reset support the steady support pole and reset.

Further, one side that the stable support pole is located and accomodates the intracavity is equipped with a pair of locking piece, the outside of shrink control lever is excavated have with locking piece assorted locking draw-in groove, and mutually supporting of a pair of locking piece of accessible and locking draw-in groove carries out the locking spacingly to the stable support pole, be connected with the locking spring between locking piece and the stable support pole, the shrink of accessible locking spring pops out control with reseing the locking piece.

Furthermore, the movable sampling mechanism comprises a sampling cylinder, so that the sampling treatment of the area needing geological investigation can be conveniently carried out through the rotation and movement of the sampling cylinder, a plurality of driving clamping grooves which are uniformly distributed are drilled on the outer side of the sampling cylinder, the sampling cylinder can be rotationally driven through the mutual matching of the plurality of driving clamping grooves and a trapezoidal clamping block, one side of the sampling cylinder, which is far away from the fixed supporting plate, is provided with a clamping limiting part, the sampling cylinder can be clamped, limited and rotationally driven through the clamping limiting part, a trapezoidal clamping block is arranged between the clamping limiting part and the sampling cylinder, the trapezoidal clamping block is matched with the driving clamping grooves, the sampling cylinder can be clamped and rotationally driven through the trapezoidal clamping block, one side of the trapezoidal clamping block, which is far away from the sampling cylinder, is connected with a clamping spring, the clamping spring plays a role of connecting the trapezoidal clamping block with the limiting part, and one side of the clamping limiting part, which is far away from the clamping limiting part, is provided with an electromagnet, the popping and resetting states of the trapezoidal clamping block can be controlled by controlling the power-on state of the electromagnet.

Further, the outside sliding connection of block locating part has the lift control, and the lift control plays the effect that supports spacing and lift control to the block locating part, one side that the sampling barrel was kept away from to the lift control is connected with the rotating electrical machines, the output shaft and the block locating part transmission of rotating electrical machines are connected, and the rotating electrical machines plays the effect that provides power, is convenient for carry out rotation control to the block locating part through the running state of control rotating electrical machines, the equal threaded connection in both sides of lift control has the lift lead screw, and accessible lift lead screw plays screw locking and lift control's effect to the lift control.

Furthermore, a lifting chute matched with the lifting control piece is drilled in the investigation sampling cylinder, the lifting control piece can be moved and limited through the lifting chute, one side of each pair of lifting screw rods, which is far away from the fixed support plate, is connected with a driving belt wheel, the driving belt wheel plays a role in rotationally driving the lifting screw rods, the outer side of the driving belt wheel is connected with a driving belt, the driving belt plays a role in connecting the driving belt wheel with a double-groove transmission belt wheel, so that the driving belt wheel correspondingly rotates along with the rotation of the double-groove transmission belt wheel under the action of the driving belt, one side of the driving belt, which is far away from the driving belt wheel, is connected with the double-groove transmission belt wheel, the double-groove transmission belt wheel plays a role in transmitting the power of lifting power, one side of the investigation sampling cylinder is connected with a lifting motor, the double-groove transmission belt wheel is connected with an output shaft of the lifting motor, and the lifting motor plays a role in transmitting power, the running state of accessible control elevator motor controls the rotating state of double flute driving pulley to be convenient for play the control action to the elevating state of block locating part.

Compared with the prior art, the invention has the following advantages:

according to the invention, the structure of the geological mineral exploration device is optimized and improved, so that the convenience of the geological mineral exploration device in the use process is obviously improved, the labor intensity of transportation and positioning of the geological mineral exploration device in the use process is reduced, and the use stability of the geological mineral exploration device is greatly improved.

Drawings

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

FIG. 1 is a perspective view of a geological mineral exploration apparatus in accordance with an embodiment of the present invention;

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

FIG. 3 is a front cross-sectional view of a geological mineral exploration apparatus in an embodiment of the present invention;

FIG. 4 is a schematic view of the structure of FIG. 3 at B;

FIG. 5 is a schematic view of the structure of FIG. 3 at C;

FIG. 6 is a schematic view of the structure of FIG. 3 at D;

FIG. 7 is a schematic view of the structure at E in FIG. 3;

FIG. 8 is a schematic view of the structure at F in FIG. 3;

fig. 9 is a top view of a geological mineral exploration apparatus in an embodiment of the present invention.

In the figure: 1. surveying sampling cylinder, 101 supporting fixed ring, 2 retractable supporting mechanism, 201 fixed supporting plate, 202 folding triangular supporting plate, 203 fixed column, 204 limiting cylinder, 205 contracting spring, 206 fixed ground nail, 207 crushing cone head, 208 driving control piece, 209 driving control rod, 210 limiting pin shaft, 211 moving supporting piece, 212 restoring spring, 213 stabilizing supporting rod, 214 hinged support, 215 contracting control rod, 216 receiving cavity, 217 supporting spring, 218 locking block, 219 locking spring, 3 moving sampling mechanism, 301 sampling cylinder, 302 clamping limit piece, 303 trapezoidal clamping block, 304 clamping spring, 305 electromagnet, 306 lifting control piece, 307 rotating motor, 308 lifting screw rod, 309 driving belt wheel, 310 driving belt, 311 double-groove driving belt wheel, 312 lifting motor, 4. The clamping device comprises a clamping stabilizing mechanism 401, a fixed limiting box 402, an arc-shaped guide piece 403, a guide spring 404, a guide roller 405 and a rotating shaft.

Detailed Description

The present invention will be described in detail below with reference to embodiments shown in the drawings. The embodiments are not intended to limit the present invention, and structural, methodological or functional changes made by those skilled in the art according to the embodiments are included in the scope of the present invention.

The invention discloses a geological mineral exploration device, which is shown in figures 1-9 and comprises an exploration sampling cylinder 1, a retractable supporting mechanism 2 and a movable sampling mechanism 3.

Referring to fig. 1, a supporting and fixing ring 101 is connected to one side of an investigation sampling cylinder 1, and the supporting and fixing ring 101 can be acted by a force to assist in stabilizing the investigation sampling cylinder 1.

Referring to fig. 1, the retractable supporting mechanism 2 is disposed on one side of the investigation sampling cylinder 1, and the retractable supporting mechanism 2 can support and fix the investigation sampling cylinder 1, so that the stability of supporting and fixing the investigation sampling cylinder 1 is improved.

Referring to fig. 1-2, the retractable supporting mechanism 2 includes a fixed supporting plate 201, the fixed supporting plate 201 is located below the investigation sampling cylinder 1 and is connected to the investigation sampling cylinder 1, and the fixed supporting plate 201 supports and fixes the investigation sampling cylinder 1.

Referring to fig. 1-2, one side of the fixed supporting plate 201 away from the investigation sampling cylinder 1 is hinged with a plurality of uniformly distributed folding triangular supporting plates 202, and the fixed supporting plate 201 can be supported and fixed in a manner of fixing and limiting the plurality of folding triangular supporting plates 202, so that the use stability of the investigation sampling cylinder 1 is improved.

Wherein, all cut spacing fixed orifices on a plurality of folding triangular support plate 202, the fixed column 203 is installed spacingly to a plurality of spacing fixed orifices of accessible.

Referring to fig. 1-2, fixing posts 203 are disposed in the limiting fixing holes, and the folding triangular support plate 202 can be fixed and limited through the fixing posts 203, so that convenience in fixing and limiting the folding triangular support plate 202 is improved.

Referring to fig. 1-4, a plurality of limiting cylinders 204 are uniformly distributed on the outer side of the fixing column 203, and the limiting cylinders 204 support and limit the retraction spring 205.

Referring to fig. 1-4, a retraction spring 205 is disposed in the limiting cylinder 204, and the fixed ground nail 206 can be supported and limited by the retraction and restoration of the retraction spring 205.

Referring to fig. 1 to 4, a fixed ground pin 206 is disposed in the retraction spring 205, the fixed ground pin 206 is matched with the retraction spring 205, and the fixed ground pin 206 can assist in fixing the foldable triangular support plate 202, thereby improving the stability of fixing the foldable triangular support plate 202.

Referring to fig. 1-4, the side of the fixing pillar 203 far from the investigation sampling cartridge 1 is hinged with a plurality of crushing cone heads 207, and the fixing cone heads 207 can be formed by the mutual matching of the plurality of crushing cone heads, so as to support and fix the folding triangular supporting plate 202.

Referring to fig. 1 to 4, a driving control member 208 is disposed between the plurality of crushing cone heads 207, and the crushing cone heads 207 can be controlled to be spread by pressing by the movement of the driving control member 208.

Specifically, a driving control cavity matched with the driving control member 208 is drilled in the fixing column 203, and the driving control cavity is drilled to provide a movement space for the driving control member 208.

With reference to fig. 1 to 4, the side of the driving control member 208 remote from the crushing cone 207 is articulated with a plurality of evenly distributed driving control rods 209, and the driving control member 208 can be controlled in its movement by the movement of the driving control rods 209.

Referring to fig. 1 to 4, a limit pin 210 is hinged between the plurality of driving control rods 209 and the fixing column 203, and the limit pin 210 plays a role in supporting and limiting the driving control rods 209, so that the driving control rods 209 perform a rotational motion along the limit pin 210 when being subjected to an external force.

Referring to fig. 1-4, the end of the driving control rod 209 away from the driving control member 208 is hinged with a movable support 211, and the movable support 211 is matched with the fixed nail 206, so that the driving control rod 209 can be driven and controlled by the movement of the movable support 211.

As shown in fig. 1 to 4, a return spring 212 is connected between the moving support 211 and the fixed column 203, so that the moving support 211 is supported and controlled by the contraction and return of the return spring 212.

Referring to fig. 3-5, a stable supporting mechanism is connected between the folding triangular supporting plate 202 and the supporting fixing ring 101, and the stable supporting mechanism includes a plurality of stable supporting rods 213, and the plurality of stable supporting rods 213 can assist in supporting the investigation sampling cartridge 1.

Referring to fig. 3 to 5, hinged supports 214 are hinged between the plurality of stabilizing support rods 213 and the foldable triangular support plate 202, and the hinged supports 214 function to connect the stabilizing support rods 213 and the foldable triangular support plate 202, so that the foldable triangular support plate 202 can be supported and limited by the stabilizing support rods 213.

Referring to fig. 3-5, a retraction control rod 215 is disposed on a side of the stabilizing support rod 213 away from the hinge support 214, the retraction control rod 215 is hinged to the support fixing ring 101, and the retraction control rod 215 serves to connect the stabilizing support rod 213 to the support fixing ring 101.

Specifically, the retraction control rod 215 has a receiving cavity 216 bored therein to match with the stabilizing support rod 213, and the retraction control function of the stabilizing support rod 213 can be performed through the receiving cavity 216.

Referring to fig. 3 to 5, a support spring 217 is connected between the stabilizing support rod 213 and the retracting control rod 215, the support spring 217 is disposed in the accommodating cavity 216, and the support spring 217 serves to connect the stabilizing support rod 213 and the retracting control rod 215, and can support and restore the stabilizing support rod 213 through the retraction and restoration of the support spring 217.

Referring to fig. 3 to 5, a pair of locking blocks 218 is disposed on a side of the stabilizing support rod 213 located in the accommodating cavity 216, and a locking slot matched with the locking block 218 is bored on an outer side of the retraction control rod 215, so that the stabilizing support rod 213 can be locked and limited by the mutual matching of the pair of locking blocks 218 and the locking slot.

Referring to fig. 3 to 5, a locking spring 219 is connected between the locking block 218 and the stabilizing support rod 213, and the locking block 218 can be controlled to be ejected by the retraction and return of the locking spring 219.

Referring to fig. 2, the mobile sampling mechanism 3 is arranged in the exploration sampling cylinder 1, and the mobile sampling mechanism 3 is used for sampling and processing the address mineral products.

Referring to fig. 3-7, mobile sampling mechanism 3 includes a sampling cartridge 301 that facilitates sampling of an area for geological exploration through rotation and movement of sampling cartridge 301.

Wherein, the outside of cartridge 301 is cut and is had a plurality of evenly distributed's drive draw-in groove, and the mutually supporting of a plurality of drive draw-in grooves of accessible and trapezoidal fixture block 303 carries out rotary drive to cartridge 301.

Referring to fig. 3 to fig. 7, a clamping limiting member 302 is disposed on a side of the sampling barrel 301 away from the fixed supporting plate 201, and the clamping limiting member 302 can perform clamping limiting and rotation driving functions on the sampling barrel 301.

Referring to fig. 3 to 7, a trapezoidal fixture block 303 is disposed between the engagement limiting member 302 and the sampling barrel 301, and the trapezoidal fixture block 303 is matched with the driving slot, so that the sampling barrel 301 can be engaged and rotationally driven by the trapezoidal fixture block 303.

Referring to fig. 3-7, a side of the trapezoidal latch 303 away from the cartridge 301 is connected to a latch spring 304, and the latch spring 304 functions to connect the trapezoidal latch 303 and the latch stopper 302.

Referring to fig. 3-7, an electromagnet 305 is disposed on a side of the engagement limiting member 302 away from the engagement spring 304, and the state of the trapezoid latch 303 that is ejected and reset can be controlled by controlling the power-on state of the electromagnet 305.

Referring to fig. 3 to 7, the outer side of the engaging position-limiting member 302 is slidably connected with a lifting control member 306, and the lifting control member 306 plays a role in supporting, limiting and controlling the engaging position-limiting member 302.

Referring to fig. 3-7, a rotating motor 307 is connected to a side of the lifting control member 306 away from the sampling cylinder 301, an output shaft of the rotating motor 307 is in transmission connection with the engagement limiting member 302, and the rotating motor 307 provides power to facilitate rotation control of the engagement limiting member 302 by controlling an operating state of the rotating motor 307.

Referring to fig. 3 to 7, the lifting control member 306 is connected to the lifting screw 308 at both sides thereof, and the lifting screw 308 can lock the lifting control member 306 and control lifting.

Wherein, it has the lift spout with lift control 306 assorted to excavate in reconnaissance sampling section of thick bamboo 1, and accessible lift spout plays the spacing effect of removal to lift control 306.

Referring to fig. 3 to 7, driving pulleys 309 are connected to the sides of the pair of lifting screws 308 away from the fixed support plate 201, and the driving pulleys 309 drive the lifting screws 308 to rotate.

Referring to fig. 3 to 7, a transmission belt 310 is connected to an outer side of the driving pulley 309, and the transmission belt 310 serves to connect the driving pulley 309 and the double groove transmission pulley 311 such that the driving pulley 309 rotates correspondingly with the rotation of the double groove transmission pulley 311 by the transmission belt 310.

Referring to fig. 3 to 7, a double-groove driving pulley 311 is connected to a side of the driving belt 310 away from the driving pulley 309, and the double-groove driving pulley 311 functions to transmit power of the elevating motor 312.

Referring to fig. 3 to 7, a lifting motor 312 is connected to one side of the investigation sampling cylinder 1, a double-groove transmission belt wheel 311 is connected to an output shaft of the lifting motor 312, the lifting motor 312 plays a role in transmitting power, and the rotation state of the double-groove transmission belt wheel 311 can be controlled by controlling the operation state of the lifting motor 312, so that the lifting state of the clamping limiting member 302 can be controlled.

Wherein, one side that elevator motor 312 was kept away from to cartridge 301 is equipped with a plurality of evenly distributed's centre gripping stabilizing mean 4, and accessible centre gripping stabilizing mean 4 plays the stable effect of centre gripping to cartridge 301, has improved cartridge 301's sampling stability.

Referring to fig. 3-8, the clamping and stabilizing mechanism 4 includes a fixed position-limiting box 401, and the arc-shaped guide member 402 can be supported and limited by the fixed position-limiting box 401.

Referring to fig. 3-8, an arc-shaped guide part 402 is arranged in the fixed limit box 401, and the sampling cartridge 301 can be clamped and limited by the mutual matching of the arc-shaped guide parts 402, so that the sampling stability of the sampling cartridge 301 is improved.

Referring to fig. 3-8, a guide spring 403 is connected between the arc-shaped guide 402 and the fixed limit box 401, and the guide spring 403 plays a role in connecting the arc-shaped guide 402 and the fixed limit box 401, and the arc-shaped guide 402 can be supported and limited by the contraction and the reset of the guide spring 403.

Referring to fig. 3-8, the arc-shaped guide member 402 is provided with a plurality of uniformly distributed guide rollers 404 on the side away from the guide spring 403, so that the sampling cartridge 301 can be stably clamped by the plurality of guide rollers 404.

Referring to fig. 3-8, a rotating shaft 405 is connected to the guiding roller 404, and the rotating shaft 405 is rotatably connected to the arc-shaped guiding member 402, so that the guiding roller 404 can be supported and limited by the rotating shaft 405.

When the sampling cylinder 1 is used specifically, when the sampling cylinder 1 is installed and fixed, the folding triangular support plates 202 can be unfolded, the folding triangular support plates 202 are primarily fixed in a mode of applying acting force to the fixing columns 203, and when the fixing columns 203 are in contact with the fixing ground nails 206, the fixing ground nails 206 play a role in assisting in fixing the folding triangular support plates 202;

meanwhile, when the movable support piece 211 is in contact with the fixed ground nail 206, the movable support piece 211 compresses the return spring 212, the driving control piece 208 moves along with the movement of the movable support piece 211 under the action of the driving control rod 209, the plurality of crushing cone heads 207 can be unfolded through the movement of the driving control piece 208, the fixed column 203 can be subjected to auxiliary fixing and limiting effects through the unfolding of the crushing cone heads 207, and the stability of fixing the fixed support plate 201 is improved;

then, a user can place the sampling cylinder 301 in the investigation sampling cylinder 1, preliminarily fasten the sampling cylinder 301 through the fastening limiting piece 302, fasten and limit the sampling cylinder 301 through the mutual cooperation of the trapezoidal fastening block 303 and the driving fastening groove at the outer side of the sampling cylinder 301, and then, control the rotation of the fastening limiting piece 302 and the sampling cylinder 301 through controlling the operation of the rotating motor 307;

the double-groove transmission belt wheel 311 is rotationally driven by controlling the operation of the lifting motor 312, the driving belt wheel 309 correspondingly rotates along with the rotation of the double-groove transmission belt wheel 311 under the action of the transmission belt 310, the lifting screw rod 308 is drivingly controlled by the rotation of the driving belt wheel 309, when the lifting screw rod 308 rotates, the lifting control piece 306 drives the clamping limiting piece 302 to move up and down under the interaction of internal threads and external threads, and the geological mineral products are sampled by the rotation and the lifting movement of the sampling cylinder 301;

in the sampling process of the sampling cartridge 301, the arc-shaped guide piece 402 and the guide roller 404 can be matched with each other to support and limit the sampling cartridge 301, so that the sampling and exploration stability of the sampling cartridge 301 on geological mineral products is improved.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (10)

1. A geological mineral exploration apparatus, comprising:

the device comprises an investigation sampling cylinder (1), wherein one side of the investigation sampling cylinder (1) is connected with a supporting and fixing ring (101);

the retractable supporting mechanism (2) is arranged on one side of the exploration sampling barrel (1), the retractable supporting mechanism (2) comprises a fixed supporting plate (201), the fixed supporting plate (201) is positioned below the exploration sampling barrel (1) and is connected with the exploration sampling barrel (1), one side, far away from the exploration sampling barrel (1), of the fixed supporting plate (201) is hinged with a plurality of uniformly distributed folding triangular supporting plates (202), a plurality of limiting fixing holes are formed in the folding triangular supporting plates (202), fixing columns (203) are arranged in the limiting fixing holes, a plurality of uniformly distributed limiting barrels (204) are arranged on the outer sides of the fixing columns (203), contraction springs (205) are arranged in the limiting barrels (204), fixing ground nails (206) are arranged in the contraction springs (205), and the fixing ground nails (206) are matched with the contraction springs (205), a stable supporting mechanism is connected between the folding triangular supporting plate (202) and the supporting fixing ring (101);

the mobile sampling mechanism (3) is arranged in the investigation sampling cylinder (1), and the mobile sampling mechanism (3) is used for sampling and processing the address mineral products.

2. A geological mineral exploration arrangement according to claim 1, characterized in that said fixed column (203) is hinged with a plurality of crushing cone heads (207) at a side remote from the exploration sampling cartridge (1), a driving control member (208) is provided between said plurality of crushing cone heads (207), and a driving control cavity matching with the driving control member (208) is bored in said fixed column (203).

3. A geological mineral exploration device according to claim 2, characterized in that said side of said driving control (208) remote from said head (207) is hinged with a plurality of driving levers (209) uniformly distributed, between said driving levers (209) and said fixed column (203) is hinged a limit pin (210).

4. A geological mineral exploration apparatus according to claim 3, characterized in that the end of said driving control lever (209) remote from the driving control (208) is hinged with a moving support (211), said moving support (211) being matched with a fixed ground nail (206), a return spring (212) being connected between said moving support (211) and fixed column (203).

5. A geological mineral exploration device according to claim 1, characterized in that said stabilizing and supporting mechanism comprises a plurality of stabilizing and supporting rods (213), a hinged support (214) is hinged between said plurality of stabilizing and supporting rods (213) and said folding triangular supporting plate (202), a retraction control rod (215) is arranged on the side of said stabilizing and supporting rods (213) far from said hinged support (214), and said retraction control rod (215) is hinged with said supporting and fixing ring (101).

6. A geological mineral exploration device according to claim 5, characterized in that said retraction control rod (215) has a receiving cavity (216) bored therein for accommodating said stabilizing support rod (213), a support spring (217) is connected between said stabilizing support rod (213) and said retraction control rod (215), said support spring (217) is disposed in said receiving cavity (216).

7. A geological mineral exploration device according to claim 6, characterized in that one side of said stabilizing support rod (213) inside said receiving cavity (216) is provided with a pair of locking blocks (218), the outside of said retraction control rod (215) is perforated with locking slots matching with said locking blocks (218), and a locking spring (219) is connected between said locking blocks (218) and said stabilizing support rod (213).

8. The geological mineral exploration device according to claim 1, wherein the movable sampling mechanism (3) comprises a sampling cylinder (301), a plurality of driving clamping grooves are uniformly distributed on the outer side of the sampling cylinder (301), one side of the sampling cylinder (301) far away from the fixed support plate (201) is provided with a clamping limiting part (302), a trapezoidal clamping block (303) is arranged between the clamping limiting part (302) and the sampling cylinder (301), the trapezoidal clamping block (303) is matched with the driving clamping grooves, one side of the trapezoidal clamping block (303) far away from the sampling cylinder (301) is connected with a clamping spring (304), and one side of the clamping limiting part (302) far away from the clamping spring (304) is provided with an electromagnet (305).

9. A geological mineral exploration device according to claim 8, wherein said engagement limiting member (302) is slidably connected with an elevating control member (306) at the outer side, a side of said elevating control member (306) far from said sampling cylinder (301) is connected with a rotating motor (307), an output shaft of said rotating motor (307) is in transmission connection with said engagement limiting member (302), and both sides of said elevating control member (306) are in threaded connection with an elevating screw rod (308).

10. A geological mineral exploration device according to claim 9, wherein a lifting chute matched with the lifting control member (306) is drilled in the exploration sampling cylinder (1), one side of each of the pair of lifting screws (308) far away from the fixed support plate (201) is connected with a driving pulley (309), the outer side of the driving pulley (309) is connected with a driving belt (310), one side of the driving belt (310) far away from the driving pulley (309) is connected with a double-groove driving pulley (311), one side of the exploration sampling cylinder (1) is connected with a lifting motor (312), and the double-groove driving pulley (311) is connected with an output shaft of the lifting motor (312).

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