CN218981802U - Metal ion extraction device for mineral resource investigation - Google Patents

Abstract

The utility model relates to the technical field of metal ion extraction, in particular to a metal ion extraction device for mineral resource exploration, which comprises a metal ion extraction box, a crushing box, a feed pipe, an L-shaped plate, a guide plate, a baffle plate, a filter plate, a crushing pipe, a driving motor, a linkage assembly, a spiral return conveying assembly and a rotary crushing assembly, wherein the spiral return conveying assembly is arranged on the side of the metal ion extraction box; the crushing box is detachably arranged at the top of the metal ion extraction box, and the feeding pipe is embedded and fixed at the left side of the top of the crushing box; the L-shaped plate is fixedly connected to the inner wall of the top of the crushing box. The utility model can realize crushing and circulation to continuously crush unqualified caking raw materials by screening and feedback, and can ensure the crushing uniformity and effect of the raw materials by continuously screening and feedback crushing the unqualified caking raw materials by circulation, thereby avoiding the unqualified caking raw materials from entering the metal ion extracting solution and further improving the reaction extracting effect of the raw materials and the metal ion extracting solution.

Description

Metal ion extraction device for mineral resource investigation

Technical Field

The utility model relates to the technical field of metal ion extraction, in particular to a metal ion extraction device for mineral resource exploration.

Background

The metal ion is the ion of the metal element after a certain substance is dissolved in water, namely the metal element in the substance with molecular composition, the metal ion is an important component for maintaining the osmotic balance of a multiphase system, is also an essential component for wide enzyme reaction, has the catalytic activity of enzymes, besides protein part, the metal ion is also required, namely the metal ion is a component of an enzyme active center, and in the use process, the prior metal ion extraction device for mineral resource exploration adopts a metal ion extracting solution to carry out reaction extraction, such as a raw material crushing device based on metal ion extraction for mineral resource exploration, disclosed in the patent publication No. CN216322468U, adopts the extracting solution to extract and adopts the technology of crushing the raw materials of the structure before extraction.

In the prior metal ion extraction device for mineral resource exploration, in actual use, because some caking raw materials exist in the raw materials, the raw materials are crushed before extraction, so that the mixing effect of the rear surface and the extracting solution can be improved, and the extraction effect is improved;

however, after crushing the raw material, it is difficult to avoid the existence of some unqualified large raw materials, which can be crushed by secondary grinding to reduce the phenomenon; however, due to the lack of a structure for automatically screening and reinfusion and continuously crushing a large amount of raw materials in a circulating way, a part of caking raw materials still enter the extracting solution to influence the uniform extraction effect, and therefore, the metal ion extracting device for mineral resource exploration is provided for solving the problems.

Disclosure of Invention

The utility model aims to provide a metal ion extraction device for mineral resource exploration, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present utility model provides the following technical solutions: a metal ion extraction device for mineral resource exploration comprises a metal ion extraction box, a crushing box, a feed pipe, an L-shaped plate, a guide plate, a baffle plate, a filter plate, a crushing pipe, a driving motor, a linkage assembly, a spiral return conveying assembly and a rotary crushing assembly;

the crushing box is detachably arranged at the top of the metal ion extraction box, and the feeding pipe is embedded and fixed at the left side of the top of the crushing box;

the L-shaped plate is fixedly connected to the inner wall of the top of the crushing box, the driving motor is fixedly arranged at the top of the crushing box, the linkage assembly is positioned in the L-shaped plate and is fixedly connected with the bottom end of an output shaft of the driving motor, and the driving motor provides driving for the linkage assembly;

the spiral return conveying assembly is arranged at the bottom of the L-shaped plate, the guide plate and the baffle plate are obliquely arranged and fixedly connected to the right inner wall of the crushing box, the guide plate and the baffle plate are sleeved outside the spiral return conveying assembly, the top end of the spiral return conveying assembly extends into the L-shaped plate and is connected with the bottom of the linkage assembly, and the spiral return conveying assembly is used for automatically conveying the unqualified large materials back for continuous crushing;

the filter plates are obliquely arranged and fixedly connected to the left inner wall of the crushing box, are matched with the spiral return conveying assembly, and are used for filtering and screening crushed materials;

the crushing pipe fixed connection is between the left side inner wall of crushing case and the bottom left side of stock guide, and rotatory broken subassembly is located crushing pipe, and rotatory broken subassembly is used for the raw materials to gather in the mineral resource investigation work is broken, and rotatory broken subassembly's top extends to in the L shaped plate and is connected with linkage assembly's bottom, and linkage assembly is used for guaranteeing that single drive drives spiral feed back conveying assembly and rotatory broken subassembly synchronous rotation.

Preferably, the linkage assembly comprises two chain wheels and a chain, the chain is in transmission connection with the outer sides of the two chain wheels, the top of the chain wheel positioned on the right side is fixedly connected with the bottom end of an output shaft of the driving motor, and the two chain wheels synchronously rotate under the cooperation of the chain.

Preferably, the spiral feed back conveying component comprises a circular feed back cylinder, a first filter plate, a mandrel and spiral conveying blades, wherein the circular feed back cylinder is fixedly connected to the bottom of the L-shaped plate, the first filter plate is fixedly connected to the bottom of the circular feed back cylinder, the mandrel is rotationally connected to the bottom of the L-shaped plate, the spiral conveying blades are positioned in the circular feed back cylinder and fixedly sleeved on the outer side of the mandrel, the top end of the mandrel extends into the L-shaped plate and is fixedly connected with the bottom of a sprocket on the right side, and the circular feed back cylinder, the first filter plate, the mandrel and the spiral conveying blades are matched, so that large unqualified broken blocks can be automatically returned for continuous breaking when the sprocket on the right side rotates;

the left inner wall of the round feed back barrel is provided with a guide hole positioned on the right side of the filter plate, the left inner wall of the round feed back barrel is provided with a discharge hole positioned above the guide plate, and the round feed back barrel is fixedly sleeved on the guide plate and the baffle plate.

Preferably, the rotary crushing assembly comprises a rotating shaft and a plurality of broken blades, the rotating shaft is rotatably arranged between the right side of the feeding pipe and the bottom of the L-shaped plate, the broken blades are all positioned in the crushing pipe and are fixedly connected to the outer side of the rotating shaft in a ring shape, the top end of the rotating shaft extends into the L-shaped plate and is fixedly connected with the bottom of the left sprocket, the rotating shaft is matched with the broken blades, and the broken blades can drive the broken blades to crush materials entering the crushing pipe when the left sprocket rotates.

Preferably, two cutting ferrule of equal fixedly connected with in both sides top of metal ion draws case, two L shape fixture blocks of equal fixedly connected with in both sides bottom of broken case, cutting ferrule activity cutting ferrule is on the L shape fixture block that corresponds, and broken case is through four L shape fixture blocks and four cutting ferrule cooperation and metal ion draw case detachable connection.

Preferably, the top of the left side of the metal ion extraction box is communicated with and fixed with an extracting solution inlet pipe, and the bottom of the left side of the metal ion extraction box is communicated with and fixed with a valve.

Preferably, the inner wall of the bottom of the crushing box is of a conical opening structure and is communicated with the metal ion extraction box, and the crushing box consists of a box body with an opening at the top and a box cover fixed at the top of the box body in a threaded manner.

Preferably, the crushing pipe is cooperatively arranged below the feeding pipe.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the metal ion extraction device for mineral resource investigation, the wall breaking knife can be driven to rotate when the driving motor is started through the driving motor, the linkage assembly, the rotary breaking assembly, the breaking pipe and the filter plate, so that caking raw materials can be collected and broken in mineral resource investigation, and unqualified caking raw materials can be screened and shielded by the filter plate;

2. the metal ion extraction device for mineral resource exploration can guide unqualified caking raw materials into the circular feed back cylinder when a driving motor is started to carry out crushing work through the cooperation of the arranged linkage assembly and the spiral feed back conveying assembly, automatically reinfusion the unqualified caking raw materials into the crushing pipe for continuous crushing, and under the action of continuous screening reinfusion crushing,

the crushing uniformity and effect of raw materials can be ensured, and the mode of crushing and circulating feedback continuous crushing is realized by utilizing the linkage assembly to cooperate with the single driving of the driving motor, so that driving equipment is not required to be additionally increased, and long-term energy consumption is saved;

3. according to the metal ion extraction device for mineral resource exploration, the extraction liquid inlet pipe is matched with the metal ion extraction box, so that the reaction extraction work can be performed after the metal ion extraction liquid is introduced;

4. this metal ion extraction element of mineral resources investigation, through the L shape fixture block and the cutting ferrule cooperation that set up, conveniently with broken case and the convenient group of tearing open of metal ion extraction case.

The utility model can realize crushing and circulation to continuously crush unqualified caking raw materials by screening and feedback, and can ensure the crushing uniformity and effect of the raw materials by continuously screening and feedback crushing the unqualified caking raw materials by circulation, thereby avoiding the unqualified caking raw materials from entering the metal ion extracting solution and further improving the reaction extracting effect of the raw materials and the metal ion extracting solution.

Drawings

FIG. 1 is a schematic overall perspective view of the present utility model;

FIG. 2 is a schematic view of a front cross-sectional structure of the present utility model;

FIG. 3 is an enlarged schematic cross-sectional view of the L-shaped block and ferrule connector of the present utility model;

fig. 4 is a schematic top view of the striker plate of the present utility model.

In the figure: 1. a metal ion extraction box; 101. an extracting solution inlet pipe; 2. a crushing box; 201. a feed pipe; 3. an L-shaped plate; 4. a circular feed back cylinder; 401. an introduction hole; 402. a discharge hole; 5. a rotating shaft; 6. crushing the pipe; 7. breaking the wall of the knife; 8. a sprocket; 9. a chain; 10. a driving motor; 11. a filter plate; 1101. a first flanging; 12. a mandrel; 13. spiral conveying leaves; 14. a striker plate; 15. a cutting sleeve; 16. an L-shaped clamping block; 17. a material guide plate; 1701. and a second flanging edge.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "upper", "lower", "inner", "outer", "front", "rear", "both ends", "one end", "the other end", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific direction, be configured and operated in the specific direction, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "provided," "connected," and the like are to be construed broadly, and may be fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

As shown in fig. 1 to 4, the metal ion extraction device for mineral resource exploration provided by the embodiment comprises a metal ion extraction box 1, a crushing box 2, a feeding pipe 201, an L-shaped plate 3, a material guide plate 17, a material baffle 14, a filter plate 11, a crushing pipe 6, a driving motor 10, a linkage assembly, a spiral return conveying assembly and a rotary crushing assembly;

the crushing box 2 is detachably mounted at the top of the metal ion extraction box 1, two clamping sleeves 15 are fixedly connected to the tops of two sides of the metal ion extraction box 1, two L-shaped clamping blocks 16 are fixedly connected to the bottoms of two sides of the crushing box 2, the clamping sleeves 15 are movably clamped on the corresponding L-shaped clamping blocks 16, the crushing box 2 is detachably connected with the metal ion extraction box 1 through matching of four L-shaped clamping blocks 16 and four clamping sleeves 15, the effect of convenient detachment and connection of the crushing box 2 and the metal ion extraction box 1 is achieved through clamping, the left top of the metal ion extraction box 1 is communicated and fixed with an extracting solution inlet pipe 101, the arranged extracting solution inlet pipe 101 is used for introducing extracting solution, the left bottom of the metal ion extraction box 1 is communicated and fixed with a valve, the effect of conveniently discharging extracting solution is achieved, the inner wall of the bottom of the crushing box 2 is of a conical opening structure and is communicated with the metal ion extraction box 1, the crushing box 2 is composed of a box body with an opening arranged top and a box cover which is fixed at the top of the box body through threads, and the left side of the crushing box 201 is fixed at the top of the left side of the crushing box 2;

the L-shaped plate 3 is fixedly connected to the inner wall of the top of the crushing box 2, the driving motor 10 is fixedly arranged at the top of the crushing box 2, a circular preformed hole for the output shaft of the driving motor 10 to be arranged is reserved at the top of the crushing box 2, the linkage assembly is positioned in the L-shaped plate 3 and is fixedly connected with the bottom end of the output shaft of the driving motor 10, and the driving motor 10 is used for driving the linkage assembly;

the spiral return conveying assembly is arranged at the bottom of the L-shaped plate 3, the material guide plate 17 and the material baffle 14 are obliquely arranged and fixedly connected to the right inner wall of the crushing box 2, the material guide plate 17 and the material baffle 14 are sleeved outside the spiral return conveying assembly, the top end of the spiral return conveying assembly extends into the L-shaped plate 3 and is connected with the bottom of the linkage assembly, and the spiral return conveying assembly is used for continuously crushing unqualified bulk materials by automatic return conveying;

the filter plate 11 is obliquely arranged and fixedly connected to the left inner wall of the crushing box 2, the filter plate 11 is matched with the spiral return conveying assembly, the arranged filter plate 11 is used for filtering and screening crushed materials, the front side and the rear side of the filter plate 11 are both provided with a first folding edge 1101 which is bent upwards, the distance between the front side and the rear side of the right side of the filter plate 11 is smaller than the distance between the front side and the rear side of the left side of the filter plate 11, and the filter plate 11 can be provided with a vibrator which is used for driving the filter plate 11 to vibrate on the left side of the bottom of the filter plate 11;

the crushing pipe 6 fixed connection is between the left side inner wall of crushing case 2 and the bottom left side of stock guide 17, and the bottom of crushing pipe 6 is located between two first folding edges 1101, the cooperation of crushing pipe 6 sets up in the below of inlet pipe 201, plays the effect that the material of conveniently putting into through inlet pipe 201 falls into crushing pipe 6, and rotatory crushing subassembly is located crushing pipe 6, and rotatory crushing subassembly is arranged in the raw materials of gathering in the mineral resource investigation work broken, and rotatory crushing subassembly's top extends to in the L shaped plate 3 and is connected with the bottom of linkage subassembly, and linkage subassembly is used for guaranteeing single drive control spiral feed back conveying subassembly and rotatory crushing subassembly synchronous rotation.

Specifically, the linkage subassembly includes two sprocket 8 and is in the chain 9 of tightening state, the outside at two sprocket 8 is connected in the chain 9 transmission, and the top and the output shaft bottom fixed connection of driving motor 10 that are located sprocket 8 on the right side, two sprocket 8 and the chain 9 cooperation that set up can utilize the synchronous rotation of two sprocket 8 to realize the rotatory effect in single drive synchro control two places.

Further, the spiral feed back conveying assembly comprises a circular feed back cylinder 4, a first filter plate, a mandrel 12 and a spiral conveying blade 13, wherein the circular feed back cylinder 4 is fixedly connected to the bottom of the L-shaped plate 3, the first filter plate is fixedly connected to the bottom of the circular feed back cylinder 4, the mandrel 12 is rotatably connected to the bottom of the L-shaped plate 3, a rotating hole is formed in the bottom of the L-shaped plate 3, a first bearing is fixedly sleeved in the rotating hole, the inner side of an inner ring of the first bearing is fixedly connected with the outer side of the mandrel 12, the mandrel 12 is rotatably connected to the bottom of the L-shaped plate 3 through the first bearing, the effect of rotatably supporting the mandrel 12 is achieved, the spiral conveying blade 13 is positioned in the circular feed back cylinder 4 and fixedly sleeved on the outer side of the mandrel 12, the top end of the mandrel 12 extends into the L-shaped plate 3 and is fixedly connected with the bottom of the sprocket 8 on the right side, the circular feed back cylinder 4, the first filter plate, the mandrel 12 and the spiral conveying blade 13 are matched, and the spiral conveying blade 13 can be driven to rotate when the sprocket 8 on the right side rotates, so that large blocks which are unqualified to be automatically conveyed back by the spiral conveying blade 13 to be crushed continuously;

the utility model discloses a baffle plate, including round feed back section of thick bamboo 4, set up the leading-in hole 401 that is located the filter 11 right side on the left side inner wall of round feed back section of thick bamboo 4, the right side of filter 11 and the right side of first turn-over edge 1101 all with the left side fixed mounting of round feed back section of thick bamboo 4, and the top right side of filter 11 and the bottom inner wall parallel and level of leading-in hole 401, set up the discharge port 402 that is located the deflector 17 top on the left side inner wall of round feed back section of thick bamboo 4, the front side and the rear side of deflector 17 also all are provided with a second upset edge 1701 that upwards bends, and the distance between deflector 17 left side front edge and the left side rear edge is less than the distance between deflector 17's right side front edge and the right side rear edge, the left side of deflector 17 and the left side of second turn-over edge 1701 all are in the top position of broken pipe 6, the off-size that the guide 17 is used for supplying after the screening gets into in the round feed back section of thick bamboo 4, set up the large discharge port 402 is arranged to broken pipe 6, deflector 17 and the deflector 14 and the baffle plate 14 can be fixed with the baffle plate 14 on the front side of round feed back section of thick bamboo 4 and the fixed to the baffle plate 14, the baffle plate 14 is fixed with the baffle plate 14 and the front side of the baffle plate 14 is fixed to the front side of baffle plate 14, the baffle plate is fixed on the front side of baffle plate is fixed with the baffle plate 14 and the baffle plate is fixed on the front side of baffle plate is fixed with the baffle plate 14, and the baffle plate is fixed on the baffle plate is fixed with the baffle plate inside.

Further, rotatory broken subassembly includes pivot 5 and a plurality of broken wall sword 7, pivot 5 rotates and installs between the bottom of right side and L shaped plate 3 of inlet pipe 201, wherein the right side fixedly connected with second bearing of inlet pipe 201, circular hole has been seted up to the bottom of L shaped plate 3, circular hole internal fixation cover is equipped with the third bearing, the fixed suit in the outside of the inner circle of third bearing and second bearing all with pivot 5, play and supply pivot 5 to rotate and be connected and support its effect, a plurality of broken wall sword 7 all are located broken tube 6 and are annular fixed connection in the outside of pivot 5, the top of pivot 5 extends to in the L shaped plate 3 and with the bottom fixed connection of left sprocket 8, the pivot 5 and the 7 cooperation of a plurality of broken wall sword 7 of setting can drive when the sprocket 8 of left rotates, thereby break wall sword 7 rotate, the material that gets into broken tube 6 is broken.

The application method of the embodiment is as follows: starting a driving motor 10, driving the right chain wheel 8 to rotate by the driving motor 10, driving the left chain wheel 8 to rotate by the right chain wheel 8 through a chain 9, driving the left chain wheel 8 to rotate by a rotating shaft 5, driving a mandrel 12 to rotate when the right chain wheel 8 rotates, driving a spiral conveying blade 13 to rotate, discharging raw materials collected in mineral resource exploration work or pre-stored raw materials through a feeding pipe 201, enabling the raw materials to enter a crushing pipe 6 downwards through the feeding pipe 201, enabling the raw materials to fall down on a filter plate 11, enabling the crushed raw materials to pass through the filter plate 11 and enter a metal ion extraction box 1 downwards, enabling the crushed raw materials to slide right into an guide hole 401 through the top of the filter plate 11, entering a circular feed back cylinder 4, enabling the entering unqualified caking raw materials to be conveyed upwards by a spiral conveying blade 13, enabling the unqualified raw materials which enter accidentally to flow downwards through a first filter plate, discharging unqualified caking materials which are conveyed upwards through a discharging hole 402, enabling the raw materials to enter the crushing pipe 6 downwards, enabling the crushed raw materials to fall into the filter plate 11 to pass through the filter plate 11, enabling the crushed raw materials to pass through the filter plate 11 and enter the circular feed back cylinder 4, and continuously pass through the crushing materials, and continuously filtering the broken materials, and continuously filtering the crushed raw materials;

the metal ion extracting solution is injected into the metal ion extracting box 1 through the extracting solution inlet pipe 101 to be mixed with crushed raw materials, reaction extracting work is carried out, when the crushing box 2 and the metal ion extracting box 1 are required to be disassembled subsequently, the crushing box 2 is moved upwards to drive the four L-shaped clamping blocks 16 to be separated from the corresponding clamping sleeves 15 respectively, the crushing box 2 is moved downwards when being connected, the four L-shaped clamping blocks 16 are driven to be clamped into the corresponding clamping sleeves 15 respectively, at the moment, the four clamping sleeves 15 position the crushing box 2 through the four L-shaped clamping blocks 16, and the crushing box 2 and the metal ion extracting box 1 are conveniently disassembled and assembled in a simple and convenient clamping manner through the L-shaped clamping blocks 16 and the clamping sleeves 15.

Finally, it should be noted that: the foregoing description is only a preferred embodiment of the present utility model, and the present utility model is not limited thereto, but it is to be understood that modifications and equivalents of some of the technical features described in the foregoing embodiments may be made by those skilled in the art, although the present utility model has been described in detail with reference to the foregoing embodiments. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (8)

1. The utility model provides a metal ion extraction element of mineral resources investigation, includes metal ion extraction box (1), broken case (2), inlet pipe (201), L shaped plate (3), stock guide (17), striker plate (14), filter (11), broken pipe (6), driving motor (10), linkage subassembly, spiral feed back transport assembly and rotatory broken subassembly, its characterized in that:

the crushing box (2) is detachably arranged at the top of the metal ion extraction box (1), and the feeding pipe (201) is embedded and fixed at the left side of the top of the crushing box (2);

the L-shaped plate (3) is fixedly connected to the inner wall of the top of the crushing box (2), the driving motor (10) is fixedly arranged at the top of the crushing box (2), and the linkage assembly is positioned in the L-shaped plate (3) and is fixedly connected with the bottom end of an output shaft of the driving motor (10);

the spiral return conveying assembly is arranged at the bottom of the L-shaped plate (3), the material guide plate (17) and the material baffle (14) are obliquely arranged and fixedly connected to the right inner wall of the crushing box (2), the material guide plate (17) and the material baffle (14) are sleeved outside the spiral return conveying assembly, and the top end of the spiral return conveying assembly extends into the L-shaped plate (3) and is connected with the bottom of the linkage assembly;

the filter plates (11) are obliquely arranged and fixedly connected to the left inner wall of the crushing box (2), and the filter plates (11) are matched with the spiral return conveying assembly;

the crushing pipe (6) is fixedly connected between the left side inner wall of the crushing box (2) and the left side of the bottom of the material guide plate (17), the rotary crushing assembly is positioned in the crushing pipe (6), and the top end of the rotary crushing assembly extends into the L-shaped plate (3) and is connected with the bottom of the linkage assembly.

2. A metal ion extraction apparatus for mineral resource exploration according to claim 1, wherein: the linkage assembly comprises two chain wheels (8) and a chain (9), wherein the chain (9) is in transmission connection with the outer sides of the two chain wheels (8), and the top of the chain wheel (8) positioned on the right side is fixedly connected with the bottom end of an output shaft of the driving motor (10).

3. A metal ion extraction apparatus for mineral resource exploration according to claim 2, wherein: the spiral feed back conveying assembly comprises a circular feed back cylinder (4), a first filter plate, a mandrel (12) and spiral conveying blades (13), wherein the circular feed back cylinder (4) is fixedly connected to the bottom of the L-shaped plate (3), the first filter plate is fixedly connected to the bottom of the circular feed back cylinder (4), the mandrel (12) is rotationally connected to the bottom of the L-shaped plate (3), the spiral conveying blades (13) are positioned in the circular feed back cylinder (4) and fixedly sleeved on the outer side of the mandrel (12), and the top end of the mandrel (12) extends into the L-shaped plate (3) and is fixedly connected with the bottom of a sprocket wheel (8) on the right side;

the left inner wall of the round feed back barrel (4) is provided with a guide hole (401) positioned on the right side of the filter plate (11), the left inner wall of the round feed back barrel (4) is provided with a discharge hole (402) positioned above the guide plate (17), and the round feed back barrel (4) is fixedly sleeved on the guide plate (17) and the baffle plate (14).

4. A metal ion extraction apparatus for mineral resource exploration according to claim 2, wherein: the rotary crushing assembly comprises a rotating shaft (5) and a plurality of broken wall cutters (7), wherein the rotating shaft (5) is rotatably arranged between the right side of a feeding pipe (201) and the bottom of an L-shaped plate (3), the broken wall cutters (7) are all positioned in a crushing pipe (6) and are fixedly connected to the outer side of the rotating shaft (5) in a ring shape, and the top end of the rotating shaft (5) extends into the L-shaped plate (3) and is fixedly connected with the bottom of a left chain wheel (8).

5. A metal ion extraction apparatus for mineral resource exploration according to claim 1, wherein: two clamping sleeves (15) are fixedly connected to the tops of two sides of the metal ion extraction box (1), two L-shaped clamping blocks (16) are fixedly connected to the bottoms of two sides of the crushing box (2), the clamping sleeves (15) are movably clamped on the corresponding L-shaped clamping blocks (16), and the crushing box (2) is detachably connected with the metal ion extraction box (1) through the matching of four L-shaped clamping blocks (16) and four clamping sleeves (15).

6. A metal ion extraction apparatus for mineral resource exploration according to claim 1, wherein: the top of the left side of the metal ion extraction box (1) is communicated with and fixed with an extracting solution inlet pipe (101), and the bottom of the left side of the metal ion extraction box (1) is communicated with and fixed with a valve.

7. A metal ion extraction apparatus for mineral resource exploration according to claim 1, wherein: the bottom inner wall of the crushing box (2) is of a conical opening structure and is communicated with the metal ion extraction box (1), and the crushing box (2) is composed of a box body with an opening at the top and a box cover fixed at the top of the box body through threads.

8. A metal ion extraction apparatus for mineral resource exploration according to claim 1, wherein: the crushing pipe (6) is arranged below the feeding pipe (201) in a matching way.

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