CN116213025B - Breaker for mineral exploration ore analysis - Google Patents

Abstract

The invention belongs to the field of ore analysis, and particularly provides a crusher for ore analysis in mineral exploration. According to the invention, after the sample is crushed, the sieving and the shrinking can be automatically carried out, the sample can be magnetically separated and the magnetic ore content can be measured, the diameter of the sample is changed by adjusting the crushing gap and the aperture of the screen, the manual operation steps can be reduced by automatic sieving and shrinking, the manpower is saved, errors and errors possibly caused by manual operation are avoided, and ores which are not crushed and have overlarge diameters and are sieved can be separated, so that secondary crushing is facilitated.

Description

Breaker for mineral exploration ore analysis

Technical Field

The invention relates to the field of ore analysis, in particular to a crusher for ore analysis in mineral exploration.

Background

Mineral exploration is an important branch of practical geology, has comprehensiveness, practicality, economy and policy, and is characterized in that before an ore sample is analyzed, the collected sample is processed, a representative analysis sample is obtained from an original large sample, and the original sample is required to be crushed, sieved and reduced for many times; the existing crusher can only crush ores, sieving and shrinking of the ores require manual operation, manual shrinking and other operations cannot guarantee accuracy, ore sampling requires repeated operations, samples are required to be transferred for multiple times, misoperation is easy to occur in the transferring process, and the situation that the samples remain in a container and influence the measuring result is caused by multiple times of transfer.

The prior art lacks a mineral exploration ore analysis crusher which can greatly simplify the ore analysis sample preparation process, reduce sample waste, improve sample preparation accuracy and pretreat samples to a certain extent.

Disclosure of Invention

In order to solve the existing problems, the invention provides the crusher for mineral exploration ore analysis, which can automatically screen and divide samples after crushing and can magnetically separate and weigh the samples; according to the invention, the crushing gap and the screen mesh aperture can be adjusted to achieve the required thickness of the sample, the manual sieving and shrinking can be saved, errors and errors possibly caused by manual operation are avoided, the sample is not required to be transferred for multiple times, the operation steps are reduced, in addition, the sample which is not crushed and has the oversized diameter can be separated, and secondary crushing is convenient.

The technical scheme adopted by the invention is as follows: the utility model provides a mineral exploration ore breaker for analysis, includes broken mechanism, removes static sieve mechanism, division mechanism, magnetic separation mechanism and chassis mechanism, removes the static sieve mechanism and locates the diapire under the broken mechanism, and division mechanism locates the diapire under the static sieve mechanism, and the magnetic separation mechanism symmetry locates the diapire under the division mechanism, and chassis mechanism locates the diapire under the division mechanism.

Further, crushing mechanism includes top cap mechanism, twin-roll shell, fixed roll mechanism, smooth roll mechanism, safe roll adjustment mechanism, broken drain pan and material piece collection box, and top cap mechanism locates the twin-roll shell upper roof, and fixed roll mechanism link up and locates the twin-roll shell lateral wall, and smooth roll mechanism link up and slide and locate the twin-roll shell lateral wall, and safe roll adjustment mechanism locates the twin-roll shell and keeps away from the lateral wall of fixed roll mechanism, and broken drain pan locates the twin-roll shell diapire, and the material piece is collected the box and is located the twin-roll shell lateral wall.

Further, the side wall of the double-roller shell is communicated with a material block outlet, a collecting box placing plate is arranged below the material block outlet in the outer side wall of the double-roller shell, the material block collecting box is arranged on the collecting box placing plate, a fixed roller motor mounting seat is arranged on the outer side wall of the double-roller shell, which is far away from the material block outlet, a sliding roller mounting seat is symmetrically arranged on the outer side wall of the double-roller shell, the sliding roller mounting seat is vertically symmetrically arranged, and sliding roller rollers are arranged on the side wall of the sliding roller mounting seat in a relative rotation mode.

Further, the top cover mechanism comprises a crushing pressure mechanism and a top cover body, the top cover body is arranged on the upper top wall of the double-roller shell, the crushing pressure mechanism penetrates through the upper top wall of the top cover body in a sliding manner, one side, far away from the crushing pressure mechanism, of the upper top wall of the top cover body is provided with a feeding hole in a penetrating manner, the lower bottom wall of the top cover body is provided with a feeding baffle, and the upper top wall of the top cover body is provided with a pressure mechanism mounting shell; the crushing pressure mechanism comprises a pressure plate support, a pressure plate motor, a pressure plate spring and a rotating pressure plate, wherein the pressure plate support is slidably arranged in a pressure mechanism installation shell, the pressure plate support is slidably connected with a top cover body, the pressure plate motor is arranged on a top wall of the pressure plate support, the pressure plate spring is symmetrically arranged on the top wall of the pressure plate support, the pressure plate spring is close to one end of the top cover body and fixedly connected with the pressure plate support, the pressure plate spring is far away from one end of the pressure plate cover body and fixedly connected with the pressure mechanism installation shell, the rotating pressure plate is rotationally arranged at one end of the pressure plate support, pressure nails are arranged on a circular array of the side wall of the rotating pressure plate, a power output end of the pressure plate motor is in transmission connection with a rotating pressure plate belt, the crushing pressure mechanism can provide a lower pressure force for mineral materials which cannot be successfully crushed in a large volume, so that the mineral materials are crushed more fully, when the mineral materials still cannot be crushed, the crushing pressure mechanism can slide upwards to protect the crushing mechanism, and the mineral materials continue to move along a fixed roller body and a sliding roller until discharged from a material outlet.

Further, the fixed roller mechanism comprises a fixed roller body, a fixed roller bearing, a fixed roller speed reducer and a fixed roller rotating motor, wherein the fixed roller body is communicated with the side wall of the double-roller shell, the side wall of the fixed roller body is provided with a forward spiral groove, the fixed roller bearing is symmetrically arranged on the outer side wall of the double-roller shell, the fixed roller body is rotationally connected with the fixed roller bearing, the fixed roller speed reducer is arranged on the upper top wall of the fixed roller motor mounting seat and is close to one end of the double-roller shell, the fixed roller rotating motor is arranged on the upper top wall of the fixed roller motor mounting seat and is far away from one end of the double-roller shell, and the fixed roller rotating motor power output end is in transmission connection with the fixed roller speed reducer and is in transmission connection with one end of the fixed roller body, which is close to the fixed roller motor mounting seat.

Further, the roller mechanism comprises a roller support, a roller motor mounting seat, a roller body, a roller bearing, a roller reducer and a roller rotating motor, wherein the roller support is arranged between roller rollers in a sliding mode, a reverse spiral groove is formed in the side wall of the roller body, the roller motor mounting seat is arranged on the side wall of one end of the roller support, the roller motor mounting seat is arranged on the side wall of the roller body, the roller body penetrates through the side wall of the double-roller shell, the roller bearing symmetrically penetrates through the side walls of the roller support, two ends of the roller support are close to the double-roller shell, the roller body is rotationally connected with the roller bearing, the roller reducer is arranged on the roller motor mounting seat and is close to one end of the double-roller shell, the roller rotating motor is arranged on the roller motor mounting seat and is far away from one end of the double-roller shell, a power output end of the roller rotating motor is in transmission connection with the roller reducer, and one side of the roller reducer, which is close to the double-roller shell, is in transmission connection with the roller body.

Further, safe roll adjustment mechanism includes roll adjustment backplate, electric putter and roll adjustment spring, electric putter pairwise symmetry locates on the outer lateral wall of twin roll shell is close to smooth roll support one side, the roll adjustment backplate is located on the electric putter motion end roof, the roll adjustment spring symmetry locates the lateral wall that the roll adjustment backplate is close to twin roll shell, roll adjustment spring is away from twin roll shell one end and roll adjustment backplate fixed connection, roll adjustment spring is close to twin roll shell one end and smooth roll support and is kept away from the lateral wall fixed connection of twin roll shell, thereby when roll adjustment mechanism during operation, the roll adjustment spring can drive smooth roll support motion and adjust the clearance between fixed roll body and the smooth roll body, change the broken diameter of ore, when the too big roll body of ore is unable to break, the roll is driven by the roll adjustment spring to compress to safe roll adjustment mechanism, safe roll adjustment mechanism drives the smooth roll body in order to protect the roll body.

Further, the static electricity removing screening mechanism comprises a screening box body, a screening mechanism and a static electricity removing mechanism, wherein the screening box body is arranged on the lower bottom wall of the crushing bottom shell, the screening mechanism is slidably arranged in the screening box body, the static electricity removing mechanism is arranged on the upper top wall of the screening box body, the upper top wall of the screening box body is provided with an air pipe installation groove, an annular baffle is arranged on the lower side of the air pipe installation groove in the screening box body, the outer side wall of the screening box body is communicated with a screen installation opening, push-pull sliding grooves are symmetrically arranged on the inner side wall of the screening box body, and push-pull lower rollers are rotationally arranged on the bottom wall of the push-pull sliding grooves; the screening mechanism comprises a push-pull support body, a net support and a screen, wherein the push-pull support body is arranged in a push-pull chute in a sliding manner, the lower bottom wall of the push-pull support body is in sliding connection with a push-pull lower roller, the net support is arranged on the upper top wall of the push-pull support body, the screen is arranged on the inner side wall of the net support, net rack installation buckles are symmetrically arranged on the upper top wall of the push-pull support body, a push-pull handle is arranged on the outer side wall of the push-pull support body, a semicircular baffle is arranged on the inner side wall of the push-pull support body, one end, far away from the push-pull handle, of the upper top wall of the push-pull support body is rotationally provided with a push-pull upper roller, the push-pull upper roller is in sliding connection with the top wall of the push-pull chute, net rack installation rods are symmetrically arranged on the upper top surface of the net support close to the push-pull chute end, the net rack installation rods are in clamping connection with the net rack installation buckles, and the upper top wall of the net support is symmetrically provided with a vibrating motor; the static electricity removing mechanism comprises an annular air pipe and a static electricity removing instrument, the static electricity removing instrument is arranged on the inner side wall of the screening box body, the annular air pipe is arranged in the air pipe installation groove, the static electricity removing instrument and the annular air pipe are in through connection through a hose, the static electricity removing screen mechanisms can replace screens of different specifications according to requirements, crushed mineral aggregate can be automatically screened, static electricity carried by crushed mineral aggregate can be removed, dust and fine particles generated after crushing are prevented from being adsorbed on the screens and the magnetic separation device.

Further, the dividing mechanism comprises a dividing shell and a dividing platform mechanism, the dividing shell is arranged on the lower bottom wall of the screening box, the dividing platform mechanism is arranged on the inner side wall of the dividing shell, dividing partition plates are arranged on the inner side wall of the dividing shell, which is close to one end of the push-pull handle, and one end of the dividing shell, which is far away from the push-pull handle, respectively, a platform mounting groove is symmetrically arranged on the inner side wall of the dividing shell, which is close to the push-pull chute end, a magnetic separation rotating motor is symmetrically arranged on the lower bottom wall of the dividing shell, and a magnetic separation motor roller is arranged at the power output end of the magnetic separation rotating motor; the dividing platform mechanism comprises a dividing bottom plate, dividing push plates, dividing screw rod sliding tables and dividing weighing devices, wherein the dividing screw rod sliding tables are symmetrically arranged in the platform mounting grooves, the dividing weighing devices are arranged on the lower bottom wall of the dividing screw rod sliding tables, the dividing bottom plate is arranged between the dividing screw rod sliding tables, the dividing push plates are arranged on the upper top wall of the dividing bottom plate, the dividing screw rod sliding tables comprise screw rod sliding blocks, screw rod sliding table bases, screw rod sliding table screws, screw rod sliding table guide rails and screw rod sliding table motors, the lower bottom wall of the screw rod sliding table bases is fixedly connected with the upper top wall of the dividing weighing devices, the outer side wall of the screw rod sliding table bases is fixedly connected with the side wall of the dividing bottom plate, the screw rod sliding table screws are rotationally arranged on the inner side wall of the screw rod sliding table bases, the screw rod sliding table motors are communicated with the outer side wall of the screw rod sliding table bases, the screw rod slip table motor power take off end is connected with screw rod slip table screw drive, screw rod slip table guide rail locates the screw rod slip table base inside wall and keeps away from screw rod slip table screw rod one end, screw rod slip table slider slip is located on the screw rod slip table guide rail, screw rod slip table slider is kept away from screw rod slip table guide rail one end and locates on the screw rod slip table screw rod, the division push pedal is close to division screw rod slip table lateral wall and screw rod slip table slider fixed connection, division mechanism can carry out the division to the mineral aggregate sample after broken sieving automatically, manual operation's step has been reduced, and can weigh the sample before the magnetic separation, the convenience is compared with sample weight after the magnetic separation in order to calculate the content of magnetic mineral in the sample.

Further, the magnetic separation mechanism comprises a magnetic separation material pipe, a magnetic separation rotary shell and a magnetic separation device, the magnetic separation material pipe is symmetrically arranged on the lower bottom wall of the shrinkage shell, a magnetic separation head groove is formed in the inner side wall of the magnetic separation material pipe, which is far away from the magnetic separation rotary motor, and is close to the outer side wall of the magnetic separation rotary motor, the magnetic separation rotary shell is in rolling connection with a magnetic separation motor roller, the magnetic separation rotary shell is far away from the magnetic separation rotary motor, a magnetic separation hole is formed in the magnetic separation device in a penetrating manner, the magnetic separation device comprises a magnetic separation push-pull rod, a magnetic separation electromagnet and a magnetic separation plastic head, the magnetic separation push-pull rod is in sliding connection with the inner side wall of the magnetic separation rotary shell, the magnetic separation electromagnet is arranged on the side wall of the magnetic separation push-pull rod, a magnetic separation filter screen is arranged on the top of the magnetic separation groove, the magnetic separation plastic head is arranged on one end of the magnetic separation electromagnet, and the magnetic separation mechanism can perform magnetic separation on a sample after the shrinkage, and the effect of removing magnetic minerals or measuring the content of the magnetic minerals can be achieved.

Further, the underframe mechanism comprises a underframe frame body, a discharging platform, a weighing device and a discharging container, wherein the underframe frame body is arranged on the lower bottom wall of the shrinkage shell, the weighing device is symmetrically arranged on the upper side wall of the underframe frame body in pairs, the discharging platform is arranged on the upper top wall of the weighing device, and the discharging container is symmetrically arranged on the upper top wall of the discharging platform in pairs.

The beneficial effects obtained by the invention by adopting the structure are as follows:

(1) The crusher for mineral exploration ore analysis provided by the invention can automatically crush, sieve, divide and magnetically separate ore samples, so that manual operation steps are greatly reduced, and errors caused by manual operation are avoided;

(2) The fixed roller body and the sliding roller body are provided with the spiral grooves, the two roller bodies rotate reversely, a large ore sample which cannot be crushed moves along the roller bodies, when the ore reaches the crushing pressure mechanism, the crushing pressure mechanism can provide lower pressure for the ore which is larger in volume and cannot be crushed successfully, so that the ore is crushed more fully, when the ore still cannot be crushed, the crushing pressure mechanism can slide upwards to protect the crushing mechanism, and the ore continues to move along the fixed roller bodies and the sliding roller bodies until being discharged from an outlet of a material block;

(3) The distance adjusting mechanism can adjust the gap between the fixed roller body and the sliding roller body, change the diameter of ore crushing, and compress the distance adjusting spring when the roller body with excessive ore hardness cannot be crushed, so that the safety distance adjusting mechanism drives the sliding roller to slide to protect the roller body;

(4) The static electricity removing and selecting mechanism can replace screens with different specifications according to requirements, automatically screen crushed mineral aggregates, remove static electricity carried by crushed mineral aggregates, and prevent dust and fine particles generated after crushing from being adsorbed on the screens and the magnetic separation device;

(5) The shrinkage dividing mechanism can automatically divide crushed and sieved mineral aggregate samples, reduces the steps of manual operation, can weigh the samples before magnetic separation, and is convenient to compare with the weights of the samples after magnetic separation so as to calculate the content of magnetic minerals in the samples;

(6) The magnetic separation mechanism can perform magnetic separation on the sample after shrinkage, the effect of removing magnetic minerals or measuring the content of the magnetic minerals can be achieved, and the magnetic separation groove and the magnetic separation filter screen can prevent the magnetic separation mineral aggregate from being adsorbed by the magnetic separation mechanism due to the fact that the movement speed is too high or the magnetic separation mineral aggregate is impacted.

Drawings

FIG. 1 is a schematic perspective view of a crusher for mineral exploration ore analysis according to the present invention;

fig. 2 is a schematic perspective view of a crushing mechanism according to the present invention;

FIG. 3 is a side, partial cross-sectional view of a crushing mechanism according to the present invention;

FIG. 4 is a partial view A of FIG. 3;

FIG. 5 is a front cross-sectional view of a crushing mechanism according to the present invention;

FIG. 6 is a partial view B of FIG. 5;

FIG. 7 is a top view of a combination of a twin roll housing, a fixed roll mechanism, a slip roll mechanism and a safety distance adjusting mechanism according to the present invention;

FIG. 8 is a perspective view of a de-static screen mechanism according to the present invention;

FIG. 9 is a side view in half section of a de-static screen mechanism according to the present invention;

FIG. 10 is a partial view C of FIG. 9;

fig. 11 is a schematic perspective view of a screening box according to the present invention;

fig. 12 is a schematic perspective view of a screening mechanism according to the present invention;

FIG. 13 is a partial view D of FIG. 12;

FIG. 14 is a perspective view of a combination of a dividing mechanism, a magnetic separation mechanism and a chassis mechanism according to the present invention;

FIG. 15 is a side view of a combination of the reduction mechanism, magnetic separation mechanism and chassis mechanism of the present invention;

FIG. 16 is a perspective view of a reduction platform mechanism according to the present invention;

fig. 17 is a front view of the sliding table of the division screw rod provided by the invention;

FIG. 18 is a cross-sectional view of a magnetic separator tube according to the present invention;

FIG. 19 is a schematic perspective view of a magnetic separation rotary housing according to the present invention;

fig. 20 is a schematic perspective view of a magnetic separation device according to the present invention.

Wherein 1, crushing mechanism, 2, de-static screen mechanism, 3, dividing mechanism, 4, magnetic separation mechanism, 5, chassis mechanism, 11, top cover mechanism, 12, double-roll shell, 13, fixed roll mechanism, 14, slide roll mechanism, 15, safety distance adjusting mechanism, 16, crushing bottom cover, 17, lump collecting box, 21, screening box, 22, screening mechanism, 23, de-static mechanism, 31, dividing shell, 32, dividing platform mechanism, 41, magnetic separation pipe, 42, magnetic separation rotary shell, 43, magnetic separation device, 51, bottom plate frame, 52, discharge platform, 53, weighing device, 54, discharge container, 111, crushing pressure mechanism, 1111, pressure plate bracket, pressure plate motor, 1113, pressure plate spring, 1114, rotary pressure plate, 1115, pressure nail, 112, top cover, 1121, feed inlet, 1122, pressure mechanism mounting shell, 1123, feed baffle, 121, lump outlet, 122, collecting box placing plate, 123, fixed roller motor mounting seats, 124, a sliding roller mounting seat, 1241, a sliding roller, 131, a fixed roller body, 1311, a forward spiral groove, 132, a fixed roller bearing, 133, a fixed roller speed reducer, 134, a fixed roller rotating motor, 141, a sliding roller bracket, 1411, a sliding roller motor mounting seat, 142, a sliding roller body, 1421, a reverse spiral groove, 143, a sliding roller bearing, 144, a sliding roller speed reducer, 145, a sliding roller rotating motor, 151, a distance adjusting backboard, 152, an electric push rod, 153, a distance adjusting spring, 211, an annular baffle, 212, a push-pull chute, 213, an air pipe mounting groove, 214, a screen mounting opening, 215, a push-pull lower roller, 221, a push-pull bracket body, 2211, a net rack mounting buckle, 2212, a push-pull handle, 2213, a semicircular baffle, 2214, a push-pull upper roller, 222, a net bracket, 2221, a net rack mounting rod, 2222, a vibration motor, 223, a net rack, 231, an annular air pipe, 232. the static eliminator comprises a static eliminator 311, a shrinkage separation plate 312, a platform mounting groove 313, a magnetic separation rotating motor 314, a magnetic separation motor roller 321, a shrinkage separation bottom plate 322, a shrinkage separation push plate 323, a shrinkage separation screw rod sliding table 3231, a screw rod sliding table sliding block 3232, a screw rod sliding table base 3233, a screw rod sliding table screw rod 3234, a screw rod sliding table guide rail 3235, a screw rod sliding motor 324, a shrinkage separation weighing device 411, a magnetic separation head groove 421, a magnetic separation hole 431, a magnetic separation push-pull rod 432, a magnetic separation electromagnet 4321, a magnetic separation groove 4322, a magnetic separation filter screen 433 and a magnetic separation plastic head.

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention.

Detailed Description

The invention will be described in further detail with reference to the accompanying drawings: as shown in fig. 1 to 5, the crusher for mineral exploration ore analysis comprises a crushing mechanism 1, a static removing sieve mechanism 2, a dividing mechanism 3, a magnetic separation mechanism 4 and a bottom frame mechanism 5, wherein the static removing sieve mechanism 2 is arranged on the lower bottom wall of the crushing mechanism 1, the dividing mechanism 3 is arranged on the lower bottom wall of the static removing sieve mechanism 2, the magnetic separation mechanism 4 is symmetrically arranged on the lower bottom wall of the dividing mechanism 3, and the bottom frame mechanism 5 is arranged on the lower bottom wall of the dividing mechanism 3; the crushing mechanism 1 comprises a top cover mechanism 11, a double-roller shell 12, a fixed roller mechanism 13, a sliding roller mechanism 14, a safety distance-adjusting mechanism 15, a crushing bottom shell 16 and a material block collecting box 17, wherein the top cover mechanism 11 is arranged on the upper top wall of the double-roller shell 12, the fixed roller mechanism 13 is communicated with the side wall of the double-roller shell 12, the sliding roller mechanism 14 is communicated with and slides on the side wall of the double-roller shell 12, the safety distance-adjusting mechanism 15 is arranged on the outer side wall of the double-roller shell 12 far away from the fixed roller mechanism 13, the crushing bottom shell 16 is arranged on the lower bottom wall of the double-roller shell 12, and the material block collecting box 17 is arranged on the outer side wall of the double-roller shell 12.

As shown in fig. 1 to 7, the side wall of the double-roller shell 12 is provided with a material block outlet 121 in a penetrating manner, a collecting box placing plate 122 is arranged below the material block outlet 121 on the outer side wall of the double-roller shell 12, the material block collecting box 17 is arranged on the collecting box placing plate 122, the outer side wall of the double-roller shell 12, which is far away from the material block outlet 121, is provided with a fixed roller motor mounting seat 123, the outer side wall of the double-roller shell 12 is symmetrically provided with a sliding roller mounting seat 124, the sliding roller mounting seat 124 is symmetrically arranged up and down, and the side wall of the sliding roller mounting seat 124 is relatively rotated to be provided with a sliding roller 1241.

As shown in fig. 1 to 6, the top cover mechanism 11 includes a crushing pressure mechanism 111 and a top cover 112, the top cover 112 is arranged on the upper top wall of the twin roll shell 12, the crushing pressure mechanism 111 is arranged on the upper top wall of the top cover 112 in a penetrating and sliding manner, a feeding port 1121 is arranged on one side of the upper top wall of the top cover 112 far from the crushing pressure mechanism 111 in a penetrating manner, a feeding baffle 1123 is arranged on the lower bottom wall of the top cover 112, and a pressure mechanism mounting shell 1122 is arranged on the upper top wall of the top cover 112; crushing pressure mechanism 111 includes pressure disk holder 1111, pressure disk motor 1112, pressure disk spring 1113 and rotates pressure disk 1114, pressure disk holder 1111 is slided and is located in the pressure mechanism installation shell 1122, pressure disk holder 1111 and top cap lid 112 sliding connection, pressure disk motor 1112 is located pressure disk holder 1111 upper top wall, pressure disk spring 1113 symmetry is located pressure disk holder 1111 upper top wall, pressure disk spring 1113 is close to top cap lid 112 one end and pressure disk holder 1111 fixed connection, pressure disk spring 1113 is kept away from top cap lid 112 one end and pressure mechanism installation shell 1122 fixed connection, rotate pressure disk 1114 rotation and locate pressure disk holder 1111 and keep away from pressure disk motor 1112 one end, rotate pressure disk 1114 lateral wall circular array and be equipped with press nail 1115, pressure disk motor 1112 power take off end and rotate pressure disk 1114 belt drive connection.

As shown in fig. 1 to 7, the fixed roller mechanism 13 includes a fixed roller body 131, a fixed roller bearing 132, a fixed roller reducer 133 and a fixed roller rotating motor 134, the fixed roller body 131 is through-arranged on the side wall of the double roller housing 12, a forward spiral groove 1311 is arranged on the side wall of the fixed roller body 131, the fixed roller bearing 132 is symmetrically arranged on the outer side wall of the double roller housing 12, the fixed roller body 131 is rotationally connected with the fixed roller bearing 132, the fixed roller reducer 133 is arranged on the upper top wall of the fixed roller motor mounting seat 123 and is close to one end of the double roller housing 12, the fixed roller rotating motor 134 is arranged on the upper top wall of the fixed roller motor mounting seat 123 and is far away from one end of the double roller housing 12, the power output end of the fixed roller rotating motor 134 is in transmission connection with the fixed roller reducer 133, and the fixed roller reducer 133 is in transmission connection with one end of the fixed roller body 131, which is close to the fixed roller motor mounting seat 123.

As shown in fig. 1 to 7, the roller mechanism 14 includes a roller bracket 141, a roller motor mounting seat 1411, a roller body 142, a roller bearing 143, a roller reducer 144 and a roller rotating motor 145, the roller bracket 141 is slidably disposed between roller rollers 1241, a reverse spiral groove 1421 is disposed on a side wall of the roller body 142, a roller motor mounting seat 1411 is disposed on a side wall of the roller bracket 141, which is close to the fixed roller motor mounting seat 123, a roller body 142 is disposed on a side wall of the dual-roller housing 12, the roller bearing 143 is symmetrically disposed on two sides of the roller bracket 141, which is close to the dual-roller housing 12, the roller body 142 is rotatably connected with the roller bearing 143, the roller reducer 144 is disposed on the roller motor mounting seat 1411, which is close to one end of the dual-roller housing 12, the roller rotating motor 145 is in driving connection with the roller reducer 144, and one side of the roller reducer 144, which is close to the dual-roller housing 12, is in driving connection with the roller body 142.

As shown in fig. 1 to 7, the safety distance adjusting mechanism 15 includes a distance adjusting backboard 151, an electric push rod 152 and a distance adjusting spring 153, wherein the electric push rod 152 is symmetrically arranged on one side of the outer side wall of the double-roller shell 12 close to the sliding roller support 141, the distance adjusting backboard 151 is arranged on the top wall of the moving end of the electric push rod 152, the distance adjusting spring 153 is symmetrically arranged on the side wall of the distance adjusting backboard 151 close to the double-roller shell 12, one end of the distance adjusting spring 153 away from the double-roller shell 12 is fixedly connected with the distance adjusting backboard 151, and one end of the distance adjusting spring 153 close to the double-roller shell 12 is fixedly connected with the side wall of the sliding roller support 141 away from the double-roller shell 12.

As shown in fig. 1 to 13, the static removing sieve mechanism 2 comprises a sieve box 21, a sieve mechanism 22 and a static removing mechanism 23, wherein the sieve box 21 is arranged on the lower bottom wall of the crushing bottom shell 16, the sieve mechanism 22 is slidably arranged in the sieve box 21, the static removing mechanism 23 is arranged on the upper top wall of the sieve box 21, the upper top wall of the sieve box 21 is provided with an air pipe mounting groove 213, the lower side of the air pipe mounting groove 213 in the sieve box 21 is provided with an annular baffle 211, the outer side wall of the sieve box 21 is communicated with a sieve mounting opening 214, push-pull sliding grooves 212 are symmetrically arranged on the inner side wall of the sieve box 21, and push-pull sliding grooves 212 are rotatably provided with push-pull lower rollers 215 on the bottom wall of the push-pull sliding grooves 212; the screening mechanism 22 comprises a push-pull support body 221, a net support 222 and a screen 223, wherein the push-pull support body 221 is arranged in a push-pull chute 212 in a sliding manner, the lower bottom wall of the push-pull support body 221 is in sliding connection with a push-pull lower roller 215, the net support 222 is arranged on the upper top wall of the push-pull support body 221, the screen 223 is arranged on the inner side wall of the net support 222, net support mounting buckles 2211 are symmetrically arranged on the upper top wall of the push-pull support body 221, a push-pull handle 2212 is arranged on the outer side wall of the push-pull support body 221, a semicircular baffle 2213 is arranged on the inner side wall of the push-pull support body 221, a push-pull upper roller 2214 is rotatably arranged at one end of the upper top wall of the push-pull support body 221 far away from the push-pull handle 2212, the push-pull upper roller 2214 is in sliding connection with the top wall of the push-pull chute 212, net support 222 is symmetrically provided with net support mounting rods 2221 which are clamped with net support mounting buckles 2211, and vibration motors 2222 are symmetrically arranged on the upper top wall of the net support 222; the static electricity removing mechanism 23 comprises an annular air pipe 231 and a static electricity removing instrument 232, the static electricity removing instrument 232 is arranged on the inner side wall of the screening box body 21, the annular air pipe 231 is arranged in the air pipe mounting groove 213, and the static electricity removing instrument 232 and the annular air pipe 231 are connected through a hose.

As shown in fig. 1 to 17, the division mechanism 3 comprises a division shell 31 and a division platform mechanism 32, the division shell 31 is arranged on the lower bottom wall of the screening box 21, the division platform mechanism 32 is arranged on the inner side wall of the division shell 31, a division partition plate 311 is arranged on the inner side wall of the division shell 31, which is close to one end of the push-pull handle 2212, and is far away from one end of the push-pull handle 2212, platform mounting grooves 312 are symmetrically arranged on the inner side wall of the division shell 31, which is close to the end of the push-pull chute 212, a magnetic separation rotating motor 313 is symmetrically arranged on the lower bottom wall of the division shell 31, and a magnetic separation motor roller 314 is arranged at the power output end of the magnetic separation rotating motor 313; the division platform mechanism 32 comprises a division bottom plate 321, a division push plate 322, a division screw sliding table 323 and a division weighing device 324, wherein the division screw sliding table 323 is symmetrically arranged in a platform mounting groove 312, the division weighing device 324 is arranged on the lower bottom wall of the division screw sliding table 323, the division bottom plate 321 is arranged between the division screw sliding tables 323, the division push plate 322 is arranged on the upper top wall of the division bottom plate 321, the division screw sliding table 323 comprises a screw sliding table sliding block 3231, a screw sliding table base 3232, a screw sliding table screw 3233, a screw sliding guide 3234 and a screw sliding motor 3235, the lower bottom wall of the screw sliding table base 3232 is fixedly connected with the upper top wall of the division weighing device 324, the outer side wall of the screw sliding table base 3232 is fixedly connected with the side wall of the division bottom plate 321, the screw sliding table 3233 is rotatably arranged on the inner side wall of the screw sliding table base 3232, the screw motor 3235 is communicated with the outer side wall of the screw sliding table base 3232, the power output end of the screw sliding table motor 3235 is in transmission connection with the screw sliding table 3233, the screw sliding guide 3234 is arranged on the inner side wall of the screw sliding table base 3232, one end of the screw sliding table sliding block 3233 is arranged on the sliding table guide 3231, the sliding guide 3231 is in sliding table guide 3234 is arranged on the sliding table guide 3231, the sliding table end of the sliding table is far away from the screw sliding table guide 3234, and the sliding table side of the sliding table is connected with the sliding table 3232 is close to the sliding table 32.

As shown in fig. 1 to 20, the magnetic separation mechanism 4 comprises a magnetic separation material pipe 41, a magnetic separation rotary shell 42 and a magnetic separation device 43, the magnetic separation material pipe 41 is symmetrically arranged on the lower bottom wall of the shrinkage shell 31, a magnetic separation head slot 411 is arranged on the inner side wall of the magnetic separation material pipe 41, which is far away from the end of the magnetic separation rotary motor 313, a magnetic separation rotary shell 42 is communicated with the outer side wall of the magnetic separation rotary shell 41, which is close to the magnetic separation rotary motor 313, the magnetic separation rotary shell 42 is in rolling connection with a magnetic separation motor roller 314, a magnetic separation hole 421 is arranged on the outer side wall of the magnetic separation rotary shell 42, the magnetic separation device 43 is slidingly arranged in the magnetic separation rotary shell 42, the magnetic separation device 43 comprises a magnetic separation push-pull rod 431, a magnetic separation electromagnet 432 and a magnetic separation plastic head 433, the magnetic separation push-pull rod 431 is slidingly connected with the inner side wall of the magnetic separation rotary shell 42, the magnetic separation electromagnet 432 is circularly arranged on the side wall of the magnetic separation electromagnet 432 is provided with a magnetic separation groove 4321, a magnetic separation filter screen 4322 is arranged on the top of the magnetic separation electromagnet 433, and the magnetic separation electromagnet 432 is arranged on one end far away from the magnetic separation rod 431.

As shown in fig. 1 to 15, the chassis mechanism 5 includes a chassis frame 51, a discharging platform 52, a weighing device 53 and a discharging container 54, the chassis frame 51 is disposed on the lower bottom wall of the dividing housing 31, the weighing device 53 is symmetrically disposed on the upper side wall of the chassis frame 51, the discharging platform 52 is disposed on the upper top wall of the weighing device 53, and the discharging container 54 is symmetrically disposed on the upper top wall of the discharging platform 52.

When the ore crushing device is particularly used, ore to be crushed is put in through a feed port 1121 on the top cover mechanism 11, a feed baffle 1123 can ensure that the ore is always positioned between a fixed roller body 131 and a sliding roller body 142, a fixed roller rotating motor 134 drives the fixed roller body 131 to rotate through a fixed roller speed reducer 133, a sliding roller rotating motor 145 drives the sliding roller body 142 to rotate through a sliding roller speed reducer 144, the fixed roller body 131 and the sliding roller body 142 rotate in opposite directions, the ore is crushed and falls to a crushing bottom shell 16, the ore which cannot be crushed moves along with the rotation of the fixed roller body 131 and the sliding roller body 142 along a forward spiral groove 1311 and a reverse spiral groove 1421, a pressing plate motor 1112 on a pressing plate bracket 1111 drives a rotating pressing plate 1114 to rotate, when the ore reaches the crushing pressure mechanism 111, the ore is fixed by pressing nails and pressurized for secondary crushing through the rotating pressing of the pressing plate 1114, when the ore is excessively large in volume and the hardness and cannot be crushed, a spring 1113 contracts, the pressing plate bracket 1111 slides upwards through the crushing pressure mechanism 111 and continues to move towards a double-roller shell 12, and finally the ore is discharged through a block outlet 121 and falls into a collecting block 17 on a collecting box placed on a collecting box 122; when the ore with smaller diameter but overlarge hardness passes through the crushing mechanism 1, the distance-adjusting spring 153 compresses, the roller bracket 141 slides along the roller pulley on the roller mounting seat 124, the gap between the roller body 142 and the fixed roller body 131 increases, and the damage to the roller body caused by the overlarge hardness ore is prevented.

Crushed mineral aggregate enters the static removing screening mechanism 2, the static removing mechanism 23 generates gas capable of removing static through the static removing instrument 232 and is sprayed out through the annular air pipe 231, static carried by the crushed mineral aggregate is removed to prevent adsorption, the mineral aggregate falls on the screen 223, the vibration motor 2222 on the screen bracket 222 rotates to drive the screen 223 to vibrate to improve screening efficiency of the screening mechanism 22, the screened mineral aggregate enters the division mechanism 3, the mineral aggregate falls on the division bottom plate 321 of the division platform mechanism 32, the division weighing device 324 weighs the screened mineral aggregate, then the division screw sliding table 323 starts to work, the screw sliding table motor 3235 drives the screw sliding table screw 3233 to rotate, the screw sliding table slider 3231 slides along the screw sliding table guide rail 3234 to drive the division pushing plate 322 to move, the mineral aggregate on the division bottom plate 321 is pushed to the edge, the mineral aggregate is equally divided by the division partition plate 311 and falls into the other half of the magnetic separation mechanism 4, and then the division screw sliding table 323 moves reversely to push the mineral aggregate into the opposite magnetic separation mechanism 4.

When the mineral materials are not required to be magnetically separated, a magnetic separation push-pull rod 431 is pulled out, the mineral materials directly fall into a discharge container 54 on a discharge platform 52 after entering a magnetic separation material pipe 41 from a shrinkage mechanism 3, when the magnetic separation is required to be carried out, the magnetic separation push-pull rod 431 is pushed until a magnetic separation plastic head 433 enters a magnetic separation head slot 411, at the moment, a magnetic separation electromagnet 432 is positioned in the magnetic separation material pipe 41, the magnetic separation electromagnet 432 is electrified, a magnetic separation rotating motor 313 drives a magnetic separation rotating shell 42 to rotate through a magnetic separation motor roller 314, the mineral materials enter the magnetic separation material pipe 41 and are contacted with the magnetic separation electromagnet 432, the mineral materials enter a magnetic separation groove 4321 through a magnetic separation filter screen 4322, magnetic minerals in the mineral materials can be adsorbed by the magnetic separation electromagnet 432 and the magnetic separation filter screen 4322, the non-magnetic mineral materials fall into the discharge container 54 along with the rotation of a magnetic separation device 43, and a weighing device 53 weighs the total discharged materials and compares the obtained values with the magnetic separation weighing device 324 before the magnetic separation to obtain the content of the magnetic minerals in the mineral materials; after the measurement is finished, the magnetic separation electromagnet 432 is powered off to lose magnetism, and the magnetic separation rotating motor 313 accelerates to rotate so as to throw the magnetic mineral aggregate on the magnetic separation device 43 down and fall into the discharging container 54.

When the discharge diameter of the ore sample needs to be adjusted, the crushing diameter and the specification of the screen 223 need to be changed simultaneously, when the crushing diameter is changed, the electric push rod 152 moves to drive the distance adjusting back plate 151 to move, the distance adjusting back plate 151 drives the roller mechanism 14 to slide through the distance adjusting spring 153, and the gap between the fixed roller body 131 and the roller body 142 is changed; pulling the push-pull handle 2212, the push-pull support body 221 slides along the push-pull chute 212, the screening mechanism 22 slides out of the screen mounting opening 214, the screen 223 is replaced, and the screening mechanism 22 is pushed into the screening box 21 again to complete the replacement of the screen 223.

The present invention and its embodiments have been described above with no limitation, and the embodiments of the present invention are shown in the drawings, and the actual structure is not limited thereto, so that those skilled in the art who have the ordinary skill in the art who have the benefit of the present invention will not creatively design similar structures and examples to those of the present invention without departing from the gist of the present invention.

Claims (9)

1. The utility model provides a mineral exploration breaker for ore analysis, includes crushing mechanism (1), removes static screen mechanism (2), shrinkage separation mechanism (3), magnetic separation mechanism (4) and chassis mechanism (5), its characterized in that: the static removing sieve mechanism (2) is arranged on the lower bottom wall of the crushing mechanism (1), the dividing mechanism (3) is arranged on the lower bottom wall of the static removing sieve mechanism (2), the magnetic separation mechanism (4) is symmetrically arranged on the lower bottom wall of the dividing mechanism (3), and the underframe mechanism (5) is arranged on the lower bottom wall of the dividing mechanism (3); the crushing mechanism (1) comprises a top cover mechanism (11), a double-roller shell (12), a fixed roller mechanism (13), a sliding roller mechanism (14), a safety distance adjusting mechanism (15), a crushing bottom shell (16) and a material block collecting box (17), wherein the top cover mechanism (11) is arranged on the upper top wall of the double-roller shell (12), the fixed roller mechanism (13) is arranged on the side wall of the double-roller shell (12) in a penetrating manner, the sliding roller mechanism (14) is arranged on the side wall of the double-roller shell (12) in a penetrating manner in a sliding manner, the safety distance adjusting mechanism (15) is arranged on the outer side wall of the double-roller shell (12) far away from the fixed roller mechanism (13), the crushing bottom shell (16) is arranged on the lower bottom wall of the double-roller shell (12), and the material block collecting box (17) is arranged on the outer side wall of the double-roller shell (12);

The top cover mechanism (11) comprises a crushing pressure mechanism (111) and a top cover body (112), the top cover body (112) is arranged on the upper top wall of the double-roller shell (12), the crushing pressure mechanism (111) is arranged on the upper top wall of the top cover body (112) in a penetrating and sliding manner, a feeding hole (1121) is arranged on one side, far away from the crushing pressure mechanism (111), of the upper top wall of the top cover body (112), a feeding baffle (1123) is arranged on the lower bottom wall of the top cover body (112), and a pressure mechanism mounting shell (1122) is arranged on the upper top wall of the top cover body (112); the crushing pressure mechanism (111) comprises a pressure plate support (1111), a pressure plate motor (1112), a pressure plate spring (1113) and a rotating pressure plate (1114), wherein the pressure plate support (1111) is slidably arranged in a pressure mechanism mounting shell (1122), the pressure plate support (1111) is slidably connected with a top cover body (112), the pressure plate motor (1112) is arranged on the upper top wall of the pressure plate support (1111), the pressure plate spring (1113) is symmetrically arranged on the upper top wall of the pressure plate support (1111), one end, close to the top cover body (112), of the pressure plate spring (1113) is fixedly connected with the pressure plate support (1111), one end, far away from the top cover body (112), of the pressure plate spring (1113) is fixedly connected with the pressure mechanism mounting shell (1122), the rotating pressure plate (1114) is rotatably arranged at one end, far away from the pressure plate motor (1112), a circular array of the side wall of the rotating pressure plate (1114) is provided with pressure nails (1115), and a power output end of the pressure plate motor (1112) is in belt transmission connection with the rotating pressure plate (1114).

The fixed roller mechanism (13) comprises a fixed roller body (131), a fixed roller bearing (132), a fixed roller reducer (133) and a fixed roller rotating motor (134), the fixed roller body (131) is communicated with the side wall of the double-roller shell (12), a forward spiral groove (1311) is formed in the side wall of the fixed roller body (131), the sliding roller mechanism (14) comprises a sliding roller support (141), a sliding roller body (142), a sliding roller bearing (143), a sliding roller reducer (144) and a sliding roller rotating motor (145), the sliding roller support (141) is arranged on the double-roller shell (12) in a sliding mode, a reverse spiral groove (1421) is formed in the side wall of the sliding roller body (142), and the axis of a rotating platen (1114) is perpendicular to the axis of the fixed roller body (131) and the axis of the sliding roller body (142).

2. A mineral exploration ore analysis breaker according to claim 1, characterized in that: the fixed roller bearing (132) is symmetrically arranged on the outer side wall of the double-roller shell (12), the fixed roller body (131) is rotationally connected with the fixed roller bearing (132), the fixed roller reducer (133) is arranged on the upper top wall of the fixed roller motor mounting seat (123) and is close to one end of the double-roller shell (12), the fixed roller rotating motor (134) is arranged on the upper top wall of the fixed roller motor mounting seat (123) and is far away from one end of the double-roller shell (12), the power output end of the fixed roller rotating motor (134) is in transmission connection with the fixed roller reducer (133), and the fixed roller reducer (133) is in transmission connection with one end of the fixed roller body (131) close to the fixed roller motor mounting seat (123).

3. A mineral exploration ore analysis breaker according to claim 2, characterized in that: the utility model discloses a roller motor is characterized by comprising a roller support (141), a roller motor mounting seat (123) and a roller bearing (143), wherein the roller support (141) is close to one end lateral wall of the roller motor mounting seat (123) and is provided with a roller motor mounting seat (1411), a roller body (142) is communicated with the lateral wall of the double-roller shell (12), the roller bearing (143) is symmetrically communicated with the lateral wall of the roller support (141) which is close to the double-roller shell (12), the roller body (142) is rotationally connected with the roller bearing (143), a roller reducer (144) is arranged on the upper wall of the roller motor mounting seat (1411) and is close to one end of the double-roller shell (12), a roller rotating motor (145) is arranged on the upper wall of the roller motor mounting seat (1411) and is far away from one end of the double-roller shell (12), the power output end of the roller rotating motor (145) is in transmission connection with the roller reducer (144), and one side of the roller reducer (144) is close to the double-roller shell (12) and is in transmission connection.

4. A mineral exploration ore analysis breaker according to claim 3, characterized in that: the utility model discloses a roller machine, including material piece, shell (12) and roller support (141), material piece export (121) are link up to be equipped with to the lateral wall of two roller shell (12), material piece export (121) below of two roller shell (12) lateral wall is equipped with collects box and places board (122), material piece is collected box (17) and is located and collect on box places board (122), the lateral wall that material piece export (121) one side was kept away from to two roller shell (12) is equipped with fixed roller motor mount pad (123), the lateral wall symmetry of two roller shell (12) is equipped with roller mount pad (124), symmetry sets up from top to bottom, roller mount pad (124) lateral wall symmetry rotates and is equipped with roller gyro wheel (1241), roller gyro wheel (1241) and roller support (141) sliding connection.

5. A mineral exploration ore analysis breaker according to claim 4, wherein: the safe distance adjusting mechanism (15) comprises a distance adjusting backboard (151), an electric push rod (152) and a distance adjusting spring (153), wherein the outer side walls of the electric push rod (152) are symmetrically arranged on one side of the double-roller shell (12) close to the sliding roller support (141), the distance adjusting backboard (151) is arranged on the top wall of the moving end of the electric push rod (152), the distance adjusting spring (153) is symmetrically arranged on the side wall of the distance adjusting backboard (151) close to the double-roller shell (12), one end of the distance adjusting spring (153) away from the double-roller shell (12) is fixedly connected with the distance adjusting backboard (151), and one end of the distance adjusting spring (153) close to the double-roller shell (12) is fixedly connected with the side wall of the sliding roller support (141) away from the double-roller shell (12).

6. A mineral exploration ore analysis breaker according to claim 5, wherein: the static removing screening mechanism (2) comprises a screening box body (21), a screening mechanism (22) and a static removing mechanism (23), wherein the screening box body (21) is arranged on the lower bottom wall of the crushing bottom shell (16), the screening mechanism (22) is slidably arranged in the screening box body (21), the static removing mechanism (23) is arranged on the upper top wall of the screening box body (21), an air pipe mounting groove (213) is formed in the upper top wall of the screening box body (21), an annular baffle plate (211) is arranged on the lower side of the air pipe mounting groove (213) in the screening box body (21), a screen mounting opening (214) is formed in the outer side wall of the screening box body (21) in a penetrating mode, push-pull sliding grooves (212) are symmetrically formed in the inner side wall of the screening box body (21), and push-pull lower rollers (215) are rotatably arranged on the bottom wall of the push-pull sliding grooves (212). The screening mechanism (22) comprises a push-pull support body (221), a net support (222) and a screen (223), wherein the push-pull support body (221) is slidably arranged in a push-pull chute (212), the lower bottom wall of the push-pull support body (221) is slidably connected with a push-pull lower roller (215), the net support (222) is arranged on the upper top wall of the push-pull support body (221), the screen (223) is arranged on the inner side wall of the net support (222), net rack mounting buckles (2211) are symmetrically arranged on the upper top wall of the push-pull support body (221), push-pull handles (2212) are arranged on the outer side wall of the push-pull support body (221), semicircular baffle plates (2213) are arranged on the inner side wall of the push-pull support body (221), one end of the upper top wall far away from the push-pull handles (2212) is rotatably provided with push-pull upper rollers (2214), net rack mounting rods (2221) are symmetrically arranged on the upper top wall of the net support body (222), the upper top surface of the net support (222) close to the push-pull chute (212), and net rack mounting rods (2221) are symmetrically arranged on the upper top wall of the net rack mounting buckles (222), and the net rack mounting buckles (2221) are symmetrically arranged on the net rack motor (222). The static electricity removing mechanism (23) comprises an annular air pipe (231) and a static electricity removing instrument (232), the static electricity removing instrument (232) is arranged on the inner side wall of the screening box body (21), the annular air pipe (231) is arranged in the air pipe mounting groove (213), and the static electricity removing instrument (232) and the annular air pipe (231) are connected through a hose.

7. A mineral exploration ore analysis breaker according to claim 6, wherein: the division mechanism (3) comprises a division shell (31) and a division platform mechanism (32), the division shell (31) is arranged on the lower bottom wall of the screening box body (21), the division platform mechanism (32) is arranged on the inner side wall of the division shell (31), a division partition plate (311) is arranged on the inner side wall of the division shell (31) close to one end of the push-pull handle (2212) and one end far away from the push-pull handle (2212), platform mounting grooves (312) are symmetrically arranged on the inner side wall of the division shell (31) close to the push-pull chute (212), a magnetic separation rotating motor (313) is symmetrically arranged on the lower bottom wall of the division shell (31), and a magnetic separation motor roller (314) is arranged at the power output end of the magnetic separation rotating motor (313); the shrinkage cavity platform mechanism (32) comprises a shrinkage cavity bottom plate (321), a shrinkage cavity push plate (322), a shrinkage cavity screw sliding table (323) and a shrinkage cavity weighing device (324), the shrinkage cavity screw sliding table (323) is symmetrically arranged in a platform mounting groove (312), the shrinkage cavity weighing device (324) is arranged on the lower bottom wall of the shrinkage cavity screw sliding table (323), the shrinkage cavity bottom plate (321) is arranged between the shrinkage cavity screw sliding tables (323), the shrinkage cavity push plate (322) is arranged on the upper top wall of the shrinkage cavity bottom plate (321), the shrinkage cavity screw sliding table (323) comprises a screw sliding table sliding block (3231), a screw sliding table base (3232), a screw sliding table screw (3233), a screw sliding guide rail (3234) and a screw sliding table motor (3235), the lower bottom wall of the screw sliding table base (3232) is fixedly connected with the upper top wall of the shrinkage cavity weighing device (324), the outer side wall of the screw sliding table base (3232) is rotationally arranged on the inner side wall of the screw sliding table base (3232), the shrinkage cavity sliding table (3235) is arranged on the upper top wall of the shrinkage cavity sliding table base (321) and is communicated with the screw sliding table (3235) and is far away from the screw sliding table (3233) through the inner side wall of the screw sliding table (3235), the screw rod sliding table sliding block (3231) is arranged on the screw rod sliding table guide rail (3234) in a sliding mode, one end, away from the screw rod sliding table guide rail (3234), of the screw rod sliding block (3231) is arranged on the screw rod sliding table screw rod (3233), and the shrinkage push plate (322) is close to the side wall of the shrinkage screw rod sliding table (323) and fixedly connected with the screw rod sliding table sliding block (3231).

8. A mineral exploration ore analysis breaker according to claim 7, wherein: the magnetic separation mechanism (4) comprises a magnetic separation material pipe (41), a magnetic separation rotary shell (42) and a magnetic separation device (43), the magnetic separation material pipe (41) is symmetrically arranged on the lower bottom wall of the shrinkage shell (31), the inner side wall of the magnetic separation material pipe (41) far away from the magnetic separation rotary motor (313) is provided with a magnetic separation head groove (411), the magnetic separation rotary shell (42) is communicated with the outer side wall of the magnetic separation rotary shell (41) close to the magnetic separation rotary motor (313), the magnetic separation rotary shell (42) is in rolling connection with a magnetic separation motor roller (314), the magnetic separation rotary shell (42) far away from the magnetic separation rotary shell (313) and is communicated with a magnetic separation hole (421), the magnetic separation device (43) is slidingly arranged in the magnetic separation rotary shell (42), the magnetic separation device (43) comprises a magnetic separation push-pull rod (431), a magnetic separation electromagnet (432) and a magnetic separation head (433), the magnetic separation rod (431) is slidingly connected with the inner side wall of the magnetic separation rotary shell (42), a circular array of the electromagnet (432) is arranged on the side wall of the magnetic separation rotary rod (431), the magnetic separation rotary shell (4321) is provided with a groove (4321), the magnetic separation groove (4322) is arranged on the top of the magnetic separation rotary shell, the magnetic separation plastic head (433) is arranged at one end of the magnetic separation electromagnet (432) far away from the magnetic separation push-pull rod (431).

9. A mineral exploration ore analysis breaker according to claim 8, wherein: the chassis mechanism (5) comprises a chassis frame body (51), a discharging platform (52), a weighing device (53) and a discharging container (54), wherein the chassis frame body (51) is arranged on the lower bottom wall of the shrinkage shell (31), the weighing device (53) is symmetrically arranged on the upper side wall of the chassis frame body (51), the discharging platform (52) is arranged on the upper top wall of the weighing device (53), and the discharging container (54) is symmetrically arranged on the upper top wall of the discharging platform (52).