CN115070955A

CN115070955A - Core segmentation ware is used in geological mineral exploration

Info

Publication number: CN115070955A
Application number: CN202210705547.6A
Authority: CN
Inventors: 潘杰; 陈奕霖; 陶世旭; 张栋
Original assignee: Individual
Current assignee: Individual
Priority date: 2022-06-21
Filing date: 2022-06-21
Publication date: 2022-09-20

Abstract

The invention relates to the technical field of rock core splitting equipment, in particular to a core splitter for geological mineral exploration. According to the rock core cutting machine, a rock core is arranged in the clamp assembly, when the clamp assembly is driven by the driving module to reciprocate once, the clamp assembly cuts the rock core into two halves when passing through the saw blades, the two half shell pieces and the half rock core clamped on the two half shell pieces tilt and deflect towards the outer side wall under the action of gravity, the motor drives the screw to rotate reversely, the screw rotates reversely to drive the clamp assembly to move towards the rear end, the two pairs of saw blades respectively cut the half rock cores on the two half shell pieces which are unfolded, and therefore quarter cutting of the rock core is achieved, and quarter cutting of the rock core is facilitated.

Description

Core segmentation ware is used in geological mineral exploration

Technical Field

The invention relates to the technical field of rock core splitting equipment, in particular to a core splitter for geological mineral exploration.

Background

The core still needs to carry out bisection cutting or quartering cutting after taking a sample, half as the sample and keeping, generally be used for sample detection, solid mineral exploration working specification has clear requirements to the method of taking and the error of drilling core appearance, the instrument of taking a sample is very crude in geological mineral exploration project now, often grasp the core with two wood chips, the cutting of handheld cutting machine is very unsafe, and the cutting is inhomogeneous, inefficiency, current cutting tool is mostly suitable for the bisection cutting, when needing quartering cutting, then need take off half post core after the bisection and carry out the reclamping and cut, the efficiency is lower, and because the anchor clamps during the once cutting are not suitable for the centre gripping to half post core during the secondary cutting, still need change anchor clamps, lead to current cutting tool to have lower efficiency when quartering cutting the core, and the precision is not high.

Disclosure of Invention

In order to overcome the technical problems, the invention aims to provide a core slicer for geological mineral exploration, which is characterized in that a core is arranged in a clamp assembly, a clamping plate clamps the core under the action of an elastic module, a driving module drives the clamp assembly to reciprocate once, the clamp assembly cuts the core into two halves when passing through a saw blade, the clamp assembly loses the limit of a limit frame after passing through two limit frames at the front end, the two half shell pieces and the half core clamped on the half shell pieces tilt and deflect towards the outer side wall under the action of gravity, a motor drives a screw to rotate reversely, the screw rotates reversely to drive the clamp assembly to move towards the rear end, two pairs of saw blades respectively cut the half core on the two half shell pieces which are unfolded, so that the quarter cutting of the core is realized, the quarter cutting of the core is convenient, the half core is not required to be disassembled and disassembled again, reduce operation flow, increase cutting efficiency, it is fixed to the centre gripping of core through splint simultaneously, removal when reducing the core cutting to guarantee cutting accuracy.

The purpose of the invention can be realized by the following technical scheme:

a core slicer for geological mineral exploration comprises a base and a plurality of clamp assemblies, wherein a fixed plate is fixedly connected to the top surface of the base, supports are fixedly connected to two sides of the middle position of the top surface of the base, a shaft lever is rotatably connected to a member at the bottom ends of the two supports, a first saw blade is fixedly sleeved on the middle position of the shaft lever, two saw blades are arranged on two sides of the first saw blade and fixedly sleeved with the shaft lever, a limiting rail is fixedly connected to the top surface of the fixed plate corresponding to the two saw blades, a driving module is fixedly connected to the middle position of the end surface of the fixed plate and used for driving the clamp assemblies to reciprocate, each clamp assembly comprises a shaft center rod, two sides of the outer side wall of each shaft center rod are rotatably connected with a half-shell member, clamp plates are mounted on the inner wall of each half-shell member, and elastic modules for pushing the clamp plates are fixedly connected to two sides of the outer side wall of each half-shell member, the top surface of the base is fixedly connected with limiting frames at two sides of one end of the saw blade, the bottom end of the base is provided with a transmission module for driving a shaft rod, a rock core is arranged in a clamp assembly, a clamping plate clamps the rock core under the action of an elastic module, the drive module drives the clamp assembly to reciprocate once, and through the arrangement of the limiting frames, the two opposite limiting frames extrude and limit the half-shell parts, so that the clamp assembly keeps the rock core at a central position through the two half-shell parts when passing through the saw blade, the clamp assembly cuts the rock core into two halves when passing through the saw blade, and loses the limitation of the limiting frames after the clamp assembly passes over the two limiting frames at the front end, the two half-shell parts and the half rock core clamped on the two half-shell parts tilt and deflect towards the outer side wall under the action of gravity, a motor drives a screw to rotate reversely, and the screw reversely drives the clamp assembly to move towards the rear end, through the setting of spacing rail, when making anchor clamps subassembly expand back towards the rear end removal and pass saw bit two, position and spacing rail sliding connection between the half shell lateral wall, thereby fix half shell spare, two saw bits are two to be respectively to the cutting of the half core on two half shell spares that expand, thereby realize the quartering cutting to the core, the convenience is to the core quartering cutting, need not to load and unload half core again and cut, reduce the operation flow, increase cutting efficiency.

Further, the method comprises the following steps: a few word grooves have been seted up to the inside wall intermediate position of half shell spare, the intermediate position and the spacing rail of the lateral wall of half shell spare agree with, the shrouding has been linked firmly to the inside wall one end of half shell spare, the blow-down groove has all been seted up to the lateral wall other end both sides position of half shell spare, the splint lateral wall corresponds two blow-down groove positions and has all linked firmly fixed ear, fixed ear and the blow-down groove sliding connection who corresponds the position, the elasticity module includes the sleeve, linking firmly of telescopic lateral wall and the lateral wall of half shell spare, telescopic inside wall slides and has cup jointed the loop bar, reset spring has been linked firmly between the one end lateral wall of loop bar and the corresponding telescopic one end, the other end of loop bar links firmly with the fixed ear of next-door neighbour's position, the median suture groove has all been seted up to one side intermediate position of splint and shrouding.

The method is further characterized in that: and the two ends of the limiting rail are fixedly connected with backing plates which support the half shell parts and guide the half shell parts to be in sliding connection with the limiting rail.

The method is further characterized in that: the bottom lateral wall of axle center pole has linked firmly the slide, the one end both sides outer wall of slide has all linked firmly the projection, drive module includes the track pole, the spacing groove has been seted up to the top surface of track pole, the bottom side and the fixed plate top surface of track pole link firmly, the both ends inside wall of track pole rotates and is connected with the screw rod, the one end lateral wall of track pole has linked firmly motor one, the output of motor one is connected with the one end transmission of screw rod, both sides position all has linked firmly the spout rail in the middle of the lateral wall of track pole, projection and spout rail sliding connection are passed through to the one end of slide, the separating tank has all been seted up at the top surface both ends of track pole, the other end of slide has linked firmly joint spare, the outline is the same in the cross-section of joint spare and spacing groove, makes things convenient for loading and unloading anchor clamps subassembly.

Further, the method comprises the following steps: the bottom of joint spare is the type of falling U, and the arc inside wall of joint spare is seted up threadedly, the lateral wall both ends position annular lateral wall of screw rod is the plain noodles for when joint spare is located the separation trench position, the screw rod breaks away from with joint spare and closes soon.

Further, the method comprises the following steps: the transmission module comprises a second motor, one side of the second motor is fixedly connected with the base, the output end of the second motor is fixedly sleeved with a belt wheel apart from one end of the shaft lever, a belt is connected between the two belt wheels in a transmission manner, and the second motor drives the shaft lever to rotate through the belt and the belt wheel, so that the first saw blade and the second saw blade rotate.

Further, the method comprises the following steps: and both ends of the top surface of the track rod are fixedly connected with contact sensors which are used for controlling the rotating direction of an output shaft of the motor.

Further, the method comprises the following steps: the length of the backing plate is greater than twice the length of the half-shell, so that one clamp assembly can conveniently push the other clamp assembly after being unfolded.

The invention has the beneficial effects that:

1. the rock core is loaded into the clamp assembly through the arrangement of the second saw blade and the clamp assembly, the clamp plate clamps the rock core under the action of the elastic module, the drive module drives the clamp assembly to reciprocate once, and through the arrangement of the limit frames, the two opposite limit frames extrude and limit the half shell parts, so that the clamp assembly keeps the rock core at a central position through the two half shell parts when passing through the saw blade, the clamp assembly cuts the rock core into two halves when passing through the saw blade, and loses the limit of the limit frames after the clamp assembly passes through the two limit frames at the front end, the two half shell parts and the half rock core clamped on the two half shell parts tilt and deflect towards the outer side wall under the action of gravity, the motor drives the screw rod to rotate reversely, the screw rod rotates reversely to drive the clamp assembly to move towards the rear end, and through the arrangement of the limit rails, when the clamp assembly expands and moves towards the rear end and passes through the second saw blade, the outer side walls of the half shells are in sliding connection with the limiting rails so as to fix the half shells, two pairs of two saw blades respectively cut half cores on the two unfolded half shells, so that the quarter cutting of the cores is realized, the quarter cutting of the cores is facilitated, the half cores do not need to be assembled and disassembled again, the operation flow is reduced, and the cutting efficiency is increased;

2. through contact sensor, the setting of separating tank and screw rod, make the equal accessible time anchor clamps subassembly of loading of the front and back end of fixed plate handle the core, make an anchor clamps subassembly return stroke to the rear end removal, after the user loads the core again to another anchor clamps subassembly, right and promote another anchor clamps subassembly to the rear end, another anchor clamps subassembly and screw rod are rotatory and are driven and remove to the rear end, after another anchor clamps subassembly top hits an anchor clamps subassembly and triggers rear end contact sensor, another anchor clamps subassembly returns, realize the cutting of material loading in turn at the both ends of fixed plate, make things convenient for in batches to cut the core and handle, increase cutting efficiency.

Drawings

The invention will be further described with reference to the accompanying drawings.

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

FIG. 2 is a schematic view of a clamp assembly according to the present invention;

FIG. 3 is a schematic view of the overall front view structure of the present invention;

FIG. 4 is a structural schematic view of the clamp assembly of the present invention in an expanded state;

FIG. 5 is an enlarged view of a portion of FIG. 1 at A;

FIG. 6 is a schematic view of the structure of a position-limiting member and a position-limiting rail according to the present invention;

FIG. 7 is a schematic view of the overall top view of the present invention;

FIG. 8 is a schematic cross-sectional view of the end of the rail bar of the present invention;

FIG. 9 is a schematic view of the position structure of the chute rail according to the present invention;

fig. 10 is an exploded view of the driving module of the present invention.

In the figure: 100. a base; 110. a drive module; 111. a track rod; 112. a separation tank; 113. a screw; 114. a limiting groove; 115. a touch sensor; 116. a first motor; 117. a chute rail; 120. a fixing plate; 130. a limit rail; 131. a base plate; 140. a limiting frame; 150. a support; 160. a shaft lever; 161. a first saw blade; 162. a second saw blade; 170. a transmission module; 171. a second motor; 200. a clamp assembly; 210. a spindle rod; 211. a slide plate; 212. a convex column; 220. a half shell member; 221. a groove shaped like a Chinese character 'ji'; 222. emptying the groove; 223. closing the plate; 230. an elastic module; 231. a sleeve; 232. a loop bar; 233. a return spring; 240. a splint; 241. fixing the ear; 242. a middle slit groove; 250. a clamping piece.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to 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.

Referring to fig. 1-10, a core slicer for geological mineral exploration, includes a base 100 and a plurality of clamp assemblies 200, a fixing plate 120 is fixedly connected to a top surface of the base 100, supports 150 are fixedly connected to two sides of a middle position of the top surface of the base 100, a shaft rod 160 is rotatably connected to a bottom end of each of the two supports 150, a first saw blade 161 is fixedly sleeved at a middle position of the shaft rod 160, two saw blades 162 are respectively disposed on two sides of the first saw blade 161, the two saw blades 162 are fixedly sleeved with the shaft rod 160, a position limiting rail 130 is fixedly connected to a top surface of the fixing plate 120 corresponding to the two saw blades 162, a driving module 110 is fixedly connected to a middle position of an end surface of the fixing plate 120, the driving module 110 is used for driving the clamp assemblies 200 to reciprocate, each of the clamp assemblies 200 includes a shaft rod 210, two sides of an outer side wall of the shaft rod 210 are rotatably connected to a half shell 220, a clamp plate 240 is mounted on an inner wall of the half shell 220, two sides of the outer side wall of the half shell 220 are fixedly connected to elastic modules 230 for pushing the clamp plate 240, the top surface of the base 100 is fixedly connected with the limiting frames 140 at two side positions of two ends of the first saw blade 161, the bottom end of the base 100 is provided with the transmission module 170 for driving the shaft rod 160, the core is arranged in the clamp assembly 200, the clamping plate 240 clamps the core under the action of the elastic module 230, the drive module 110 drives the clamp assembly 200 to reciprocate once, and through the arrangement of the limiting frames 140, the two opposite limiting frames 140 extrude and limit the shell members 220, so that the core is kept at the central position by the two half shell members 220 when the clamp assembly 200 passes through the first saw blade 161, the clamp assembly 200 cuts the core into two halves when passing through the first saw blade 161, and after the clamp assembly 200 passes through the two limiting frames 140 at the front end, the limitation of the limiting frames 140 is lost, the two half shell members 220 and the core clamped thereon incline and deflect towards the outer side wall under the action of gravity, the first motor 116 drives the screw 113 to rotate reversely, 113 reversals of screw rod drive anchor clamps subassembly 200 and remove towards the rear end, setting through spacing rail 130, make anchor clamps subassembly 200 expand the back and remove when passing saw bit two 162 towards the rear end, position and spacing rail 130 sliding connection between the half shell 220 lateral wall, thereby fix half shell 220, two saw bit two 162 are to cutting the half core on half shell 220 to two expansions respectively, thereby realize the quartering cutting to the core, the convenience is to the core quartering cutting, need not to load and unload half core again and cut, reduce operation flow, increase cutting efficiency.

Several word grooves 221 have been seted up to the inside wall intermediate position of half shell 220, the intermediate position of the lateral wall of half shell 220 agrees with spacing rail 130, the inside wall one end of half shell 220 has linked firmly shrouding 223, emptying groove 222 has all been seted up to the lateral wall other end both sides position of half shell 220, splint 240 lateral wall corresponds two emptying groove 222 positions and has all linked firmly fixed ear 241, fixed ear 241 and the emptying groove 222 sliding connection who corresponds the position, elasticity module 230 includes sleeve 231, linking firmly of a lateral wall of sleeve 231 and the lateral wall of half shell 220, the inside wall slip of sleeve 231 has cup jointed loop bar 232, reset spring 233 has been linked firmly between the one end lateral wall of loop bar 232 and the one end that corresponds sleeve 231, the other end of loop bar 232 links firmly with the fixed ear 241 of next-door neighbour's position, slot 242 is all seted up to one side intermediate position of splint 240 and shrouding 223.

The two ends of the limit rail 130 are fixedly connected with backing plates 131, the backing plates 131 support the half-shell piece 220 and guide the half-shell piece 220 to be in sliding connection with the limit rail 130, the outer side wall of the bottom end of the axis rod 210 is fixedly connected with a sliding plate 211, the outer walls of the two sides of one end of the sliding plate 211 are fixedly connected with convex columns 212, the driving module 110 comprises a rail rod 111, the top surface of the rail rod 111 is provided with a limit groove 114, the bottom side of the rail rod 111 is fixedly connected with the top surface of a fixed plate 120, the inner side walls of the two ends of the rail rod 111 are rotatably connected with screw rods 113, the outer side wall of one end of the rail rod 111 is fixedly connected with a motor one 116, the output end of the motor one 116 is in transmission connection with one end of the screw rod 113, the positions of the two sides of the middle of the outer side wall of the rail rod 111 are respectively fixedly connected with a sliding groove rail 117, one end of the sliding plate 211 is slidably connected with the sliding groove 117 through the convex columns 212, the two ends of the top surface of the rail rod 111 are respectively provided with separation grooves 112, the other end of the sliding plate 211 is fixedly connected with a clamping member 250, the outer contour of the clamping member 250 is the same as the inner contour of the cross section of the limiting groove 114, so that the clamp assembly 200 can be conveniently assembled and disassembled.

The bottom end of the clamping piece 250 is inverted U-shaped, the arc-shaped inner side wall of the clamping piece 250 is provided with threads, the annular outer side walls at the two ends of the outer side wall of the screw 113 are smooth surfaces, when the clamping member 250 is located at the position of the separation groove 112, the screw 113 is disengaged from the clamping member 250, the transmission module 170 includes a second motor 171, one side of the second motor 171 is fixedly connected with the base 100, a belt wheel is fixedly sleeved between the output end of the second motor 171 and one end of the shaft rod 160, a belt is connected between the two belt wheels in a transmission way, the second motor 171 drives the shaft rod 160 to rotate through the belt and the belt wheels, so that the first saw blade 161 and the second saw blade 162 rotate, the two ends of the top surface of the track rod 111 are fixedly connected with the contact sensors 115, the contact sensors 115 are used for controlling the rotating direction of the output shaft of the first motor 116, and the length of the backing plate 131 is two times greater than that of the half shell member 220, so that one clamp assembly 200 can conveniently push the other clamp assembly 200 after being unfolded.

The working principle is as follows: when the clamp assembly 200 is used, the two half shell pieces 220 on the clamp assembly 200 are unfolded towards two sides, the clamping plate 240 on one half shell piece 220 is pushed, a rock core is placed into the half shell piece 220 on one side, the clamping plate 240 is released, the clamping plate 240 is matched with the sealing plate 223 to clamp and fix the rock core, the half shell piece 220 on the other side is closed, the clamping plate 240 on the half shell piece 220 on the other side also clamps the rock core under the action of the elastic module 230, the clamp assembly 200 is moved to slide the convex column 212 at one end of the sliding plate 211 into the sliding groove rail 117, the clamping piece 250 at the other end of the sliding plate 211 is inserted into the separating groove 112 at one end of the rail rod 111, the arc-shaped inner wall of the clamping piece 250 is contacted with the screw 113, the first motor 116 is started, the first motor 116 drives the screw 113 to rotate forwards, the two half shell pieces 220 are righted and the clamp assembly 200 is pushed towards the first saw blade 161 direction, the clamping piece 250 slides into the limiting groove 114, the clamping piece 250 is screwed with the screw 113, the screw 113 drives the clamp assembly 200 to move from the rear end to the front end through the clamping piece 250, through the arrangement of the limiting frames 140, the two opposite limiting frames 140 extrude and limit the half-shell pieces 220, so that the core is kept at the central position by the two half-shell pieces 220 when the clamp assembly 200 passes through the first saw blade 161, the core is cut into two halves when the clamp assembly 200 passes through the first saw blade 161, the limitation of the limiting frames 140 is lost after the clamp assembly 200 passes through the two limiting frames 140 at the front end, the two half-shell pieces 220 are communicated with one half of the core clamped on the two half-shell pieces 220, the core is inclined and deflected towards the outer side wall under the action of gravity, the middle position of the half-shell piece 220 after the half-shell piece 220 deflects by 90 degrees is supported by the backing plate 131, the first motor 116 drives the screw 113 to rotate reversely, the screw 113 drives the clamp assembly 200 to move towards the rear end, through the arrangement of the limiting rails 130, when the clamp assembly 200 moves towards the rear end after being unfolded and passes through the second saw blade 162, the position between the outer side walls of the half-shell pieces 220 is connected with the limiting rails 130 in a sliding manner, thereby fixing the half-shell 220, the two second saw blades 162 cut half cores of the two unfolded half-shells 220, respectively, thereby realizing quarter cutting of the cores,

through the arrangement of the contact sensor 115, the separation groove 112 and the screw 113, the front end and the rear end of the fixing plate 120 can be simultaneously provided with the clamp assemblies 200 to process the rock core, after one clamp assembly 200 at the rear end of the fixing plate 120 is provided with the rock core, the clamp assembly 200 is righted and pushed to the front end, the screw 113 rotates forward to drive the two clamp assemblies 200 to move towards the front end, the clamping piece 250 on the other clamp assembly 200 moves to be separated from the rotary joint with the screw 113, the other clamp assembly 200 stops, a user at the front end takes down and reinstalls the rock core from the other clamp assembly 200, in the operation process, one clamp assembly 200 continues to move towards the front end to contact with the other clamp assembly 200 and push the other clamp assembly 200 to contact the contact sensor 115 at the front end, the contact sensor 115 at the front end is triggered to drive the screw 113 to rotate backwards by the first motor 116, therefore, one clamp assembly 200 moves towards the rear end in a return stroke, after a user reloads a core on the other clamp assembly 200, the other clamp assembly 200 is righted and pushed towards the rear end, the other clamp assembly 200 is screwed with the screw 113 and is driven to move towards the rear end, after the other clamp assembly 200 impacts one clamp assembly 200 and triggers the rear end contact sensor 115, the other clamp assembly 200 returns, material loading and cutting at two ends of the fixing plate 120 in turn are achieved, cutting processing on the core in batches is facilitated, and cutting efficiency is improved.

In the description herein, references to the description of "one embodiment," "an example," "a specific example" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing is illustrative and explanatory only and is not intended to be exhaustive or to limit the invention to the precise embodiments described, and various modifications, additions, and substitutions may be made by those skilled in the art without departing from the scope of the invention or exceeding the scope of the claims.

Claims

1. The core slicer for geological mineral exploration is characterized by comprising a base (100) and a plurality of clamp assemblies (200), wherein a fixing plate (120) is fixedly connected to the top surface of the base (100), supports (150) are fixedly connected to two sides of the middle position of the top surface of the base (100), a shaft lever (160) is rotatably connected to a part at the bottom end of each support (150), a first saw blade (161) is fixedly sleeved at the middle position of the shaft lever (160), second saw blades (162) are arranged on two sides of the first saw blade (161), the second saw blades (162) are fixedly sleeved with the shaft lever (160), a limiting rail (130) is fixedly connected to the position, corresponding to the second saw blades (162), of the top surface of the fixing plate (120), a driving module (110) is fixedly connected to the middle position of the end surface of the fixing plate (120), and the driving module (110) is used for driving the clamp assemblies (200) to move in a reciprocating mode, the clamp assembly (200) comprises an axle center rod (210), wherein the two sides of the outer side wall of the axle center rod (210) are respectively and rotatably connected with a half shell (220), a clamping plate (240) is installed on the inner wall of the half shell (220), the two sides of the outer side wall of the half shell (220) are respectively and fixedly connected with an elastic module (230) used for pushing the clamping plate (240), the two sides of the top surface of the base (100) at the two ends of a saw blade (161) are respectively and fixedly connected with a limiting frame (140), and a transmission module (170) used for driving a shaft rod (160) is installed at the bottom end of the base (100).

2. The core slicer according to claim 1, wherein a rectangular groove (221) is formed in the middle position of the inner sidewall of the half casing (220), the middle position of the outer sidewall of the half casing (220) is engaged with the limit rail (130), one end of the inner sidewall of the half casing (220) is fixedly connected with a sealing plate (223), the other end of the outer sidewall of the half casing (220) is respectively provided with a relief groove (222), the outer sidewall of the clamping plate (240) is fixedly connected with a fixing lug (241) corresponding to the two relief grooves (222), the fixing lug (241) is slidably connected with the relief groove (222) corresponding to the corresponding position, the elastic module (230) comprises a sleeve (231), one sidewall of the sleeve (231) is fixedly connected with the outer sidewall of the half casing (220), and a sleeve rod (232) is slidably sleeved on the inner sidewall of the sleeve (231), the utility model discloses a clamp plate, including the cover rod, return spring (233) has been linked firmly between the one end lateral wall of loop bar (232) and the one end that corresponds sleeve (231), the other end of loop bar (232) links firmly with fixed ear (241) of next-door neighbour's position, slot (242) in the one side intermediate position of splint (240) and shrouding (223) all seted up.

3. The core slicer for geological mineral exploration, according to claim 2, characterized in that both ends of said limit rail (130) are attached with backing plates (131).

4. The core slicer for geological mineral exploration, according to claim 1, wherein the bottom outer side wall of the axle center rod (210) is fixedly connected with a sliding plate (211), the outer walls of both sides of one end of the sliding plate (211) are fixedly connected with a convex column (212), the driving module (110) comprises a track rod (111), the top surface of the track rod (111) is provided with a limiting groove (114), the bottom side of the track rod (111) is fixedly connected with the top surface of a fixing plate (120), the inner walls of both ends of the track rod (111) are rotatably connected with a screw rod (113), the outer wall of one end of the track rod (111) is fixedly connected with a motor I (116), the output end of the motor I (116) is in transmission connection with one end of the screw rod (113), the positions of both sides of the middle of the outer wall of the track rod (111) are fixedly connected with a sliding groove rail (117), one end of the sliding plate (211) is slidably connected with the sliding groove rail (117) through the convex column (212), separating grooves (112) are formed in two ends of the top surface of the track rod (111), a clamping piece (250) is fixedly connected to the other end of the sliding plate (211), and the outer contour of the clamping piece (250) is identical to the inner contour of the cross section of the limiting groove (114).

5. The core slicer according to claim 4, wherein the bottom of the clamping member (250) is of an inverted U shape, the arc inner side wall of the clamping member (250) is threaded, and the annular outer side wall at the two ends of the outer side wall of the screw (113) is a smooth surface.

6. The core splitter for geological mineral exploration, according to claim 1, wherein said transmission module (170) comprises a second motor (171), one side of said second motor (171) is fixedly connected to said base (100), a pulley is fixedly sleeved on the distance between the output end of said second motor (171) and one end of said shaft rod (160), and a belt is drivingly connected between said two pulleys.

7. A core splitter for geological mineral exploration, according to claim 4, characterized in that said rail bar (111) has contact sensors (115) attached to both ends of its top surface.

8. A core slicer for geological mineral exploration according to claim 3, characterized in that the length of said tie plate (131) is more than twice the length of the half shell (220).