CN212552652U - Magnetic material perforating device - Google Patents

Abstract

A magnetic material perforating device, comprising: the device comprises a magnetic core, a feeding mechanism, a positioning mechanism, a punching mechanism and a cleaning mechanism; the feeding mechanism comprises a feeding disc and a feeding channel, and the feeding disc is communicated with the feeding channel; the positioning mechanism comprises a positioning frame and a clamping mechanism, the positioning frame is arranged at the tail end of the feeding channel and comprises a placing table, the placing table is used for placing the magnetic core, and a chip leakage hole is formed in the bottom of the placing table; the two clamping mechanisms are used for clamping the magnetic core; the punching mechanism comprises a fixed frame, a hydraulic lifting rod, a rotary disc and a borer, the fixed frame is arranged above the positioning frame, and the borer and the sander are oppositely arranged at two ends of a symmetrical shaft of the rotary disc; the cleaning mechanism comprises a high-pressure air gun, and the gun head of the high-pressure air gun is arranged right opposite to the placing table. This application can realize automatic feeding, automatic drilling, the automatic sweeps of clearing up to the magnetic core, has realized streamlined production, has reduced the process, has improved production efficiency.

Description

Magnetic material perforating device

Technical Field

The utility model relates to a magnetic material processing technology field especially relates to a magnetic material perforating device.

Background

Magnetic core refers to a sintered magnetic metal oxide composed of various iron oxide mixtures. For example, manganese-zinc ferrite and nickel-zinc ferrite are typical magnetic core materials. The manganese-zinc ferrite has the characteristics of high magnetic permeability and high magnetic flux density and has the characteristic of lower loss. The nickel-zinc ferrite has the characteristics of extremely high resistivity, low magnetic permeability of less than several hundred, and the like. Ferrite cores are used in coils and transformers for various electronic devices.

In current magnetic core course of working, some magnetic cores adopt manual mode to bore a hole, because there is the difference in workman's proficiency and experience, consequently there is the inaccurate problem of drilling to need in addition to the magnetic core clearance piece after the drilling, the process is comparatively loaded down with trivial details.

SUMMERY OF THE UTILITY MODEL

Accordingly, there is a need for a magnetic material punching apparatus that can simplify the process and achieve streamlined production.

A magnetic material perforating device, comprising: the device comprises a magnetic core, a feeding mechanism, a positioning mechanism, a punching mechanism and a cleaning mechanism;

the magnetic core is of a cylindrical structure, the feeding mechanism comprises a feeding disc and a feeding channel, the magnetic core is vertically placed on the feeding disc, the feeding disc is provided with a feeding opening, the feeding channel is communicated with the feeding opening, the feeding channel comprises two parallel conveyor belts and a bottom plate, the bottom plate is arranged below the conveyor belts, the bottom plate is arranged between the two conveyor belts, the plane where the conveyor belts are located is perpendicular to the plane where the bottom plate is located, and at least one conveyor belt is arranged to be tightly attached to the magnetic core;

the positioning mechanism comprises a positioning frame and a clamping mechanism, the positioning frame is arranged at the tail end of the feeding channel and comprises a placing table, the placing table and the bottom plate are arranged on the same horizontal plane, the placing table is used for placing the magnetic core, and a chip leakage hole is formed in the bottom of the placing table; the clamping mechanism is arranged on one side of the positioning frame and comprises a workbench, a lifting cylinder, a rotating cylinder, a push-pull cylinder and a pneumatic clamping jaw, the lifting cylinder is arranged on the workbench, a lifting rod of the lifting cylinder is perpendicular to the workbench, the rotating cylinder is connected with the lifting rod, a rotating shaft of the rotating cylinder and the lifting rod are arranged in a straight line, the push-pull cylinder is connected with the rotating shaft, a push-pull rod of the push-pull cylinder is perpendicular to the rotating shaft, the pneumatic clamping jaw is connected with the push-pull rod, and a clamping part of the pneumatic clamping jaw is used for clamping the magnetic core;

the punching mechanism comprises a fixing frame, a hydraulic lifting rod, a rotating disc and a borer, the fixing frame is arranged above the positioning frame, the hydraulic lifting rod is vertically arranged, the rotating disc is horizontally arranged, the hydraulic lifting rod is arranged below the fixing frame, one end of the hydraulic lifting rod is connected with the fixing frame, the other end of the hydraulic lifting rod is connected with a disc center of the rotating disc, the borer comprises a drill rod, and one end, used for drilling the magnetic core, of the drill rod is provided with a drill bit;

the gun head of the high-pressure air gun is opposite to the placing table, and the high-pressure air gun is connected with the air compressor through an air pipe.

In one embodiment, the diameter of the clearance hole is smaller than the diameter of the magnetic core.

In one embodiment, the scrap collecting device further comprises a scrap collecting frame, wherein an opening with a large upper part and a small lower part is formed in the scrap collecting frame, the opening is arranged below the positioning frame, and the scrap leaking hole penetrates through the positioning frame.

In one embodiment, the magnetic material perforating device further comprises a protective cover which covers the magnetic material perforating device.

In one embodiment, the material receiving frame is arranged close to the workbench and below one end, provided with the clamping groove, of the clamping rod.

In one embodiment, the punching mechanism further comprises a sander, the puncher and the sander are oppositely arranged at two ends of the symmetry axis of the rotating disc, the sander comprises a sanding rod, and a sanding head is arranged at one end of the sander, which is used for sanding the magnetic core.

In one embodiment, the device further comprises an auxiliary mechanism, wherein the auxiliary mechanism comprises a supporting mechanism and a limiting mechanism,

the bearing mechanism comprises a bearing bracket and a bearing plate, the bearing bracket is arranged above the placing table, the bearing plate is arranged above the bearing bracket, a through hole is formed in the bearing plate, and when the magnetic core is placed on the placing table, the through hole is over against the magnetic core;

the limiting mechanism comprises a limiting baffle, an elastic sleeve and two guide rails, two sliding holes are formed in the rotating disc, the two sliding holes are arranged opposite to the center of the rotating disc, the guide rails are vertically arranged, the limiting baffle and the rotating disc are arranged in parallel, one end of each guide rail is fixed on the limiting baffle, the other end of each guide rail penetrates through the corresponding sliding hole in a sliding mode, and the elastic sleeve is sleeved on the guide rails;

the limiting baffle is provided with a first alignment hole and a second alignment hole, the first alignment hole is over against the drill rod, and the second alignment hole is over against the grinding rod.

In one embodiment, the limiting baffle is provided with a circular alignment hole, and the circular alignment hole is communicated with the first alignment hole and the second alignment hole.

In one embodiment, the gripping portion of the pneumatic jaw is provided with a layer of soft rubber.

The utility model has the advantages that: through feeding mechanism the positioning mechanism punch the mechanism and clearance mechanism mutually support, can realize right the automatic feeding of magnetic core, automatic drilling, automatic polishing, the automatic sweeps of clearing up have realized streamlined production, have reduced the process, have improved production efficiency.

Drawings

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

FIG. 1 is a schematic structural diagram of a magnetic material punching apparatus according to an embodiment;

FIG. 2 is a schematic view of another embodiment of a magnetic material hole punch device;

FIG. 3 is a schematic structural view of a magnetic material perforating device according to another embodiment;

fig. 4 and 5 are schematic structural views of a magnetic material punching apparatus according to still another embodiment.

Reference numerals: 10. a magnetic material punching device; 100. a magnetic core; 200. a feeding mechanism; 300. a positioning mechanism; 400. a punching mechanism; 500. a cleaning mechanism; 210. a feed tray; 220. a feed channel; 211. a feed opening; 221. a conveyor belt; 222. a base plate; 310. a positioning frame; 320. a clamping mechanism; 311. a placing table; 3111. chip leakage holes; 321. a work table; 322. a lifting cylinder; 323. a rotating cylinder; 324. a push-pull cylinder; 325. a pneumatic clamping jaw; 3251. a clamping portion; 410. a fixed mount; 420. a hydraulic lifting rod; 430. rotating the disc; 440. a drill; 450. a sander; 441. a drill rod; 442. grinding the rod; 510. a high pressure air lance; 600. a material receiving frame; 700. an auxiliary mechanism; 710. a support mechanism; 720. a limiting mechanism; 711. a support bracket; 712. a support plate; 7121. a through hole; 721. a limit baffle; 722. an elastic sleeve; 723. a guide rail; 7211. a first alignment hole; 7212. a second alignment hole; 7213. and (4) a circular alignment hole.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.

Referring to fig. 1 and fig. 2, a magnetic material punching apparatus 10 according to an embodiment of the present invention includes: the magnetic core 100, the feeding mechanism 200, the positioning mechanism 300, the punching mechanism 400 and the cleaning mechanism 500;

the magnetic core 100 is of a cylindrical structure, the feeding mechanism 200 comprises a feeding tray 210 and a feeding channel 220, the magnetic core 100 is vertically placed on the feeding tray 210, the feeding tray 210 is provided with a feeding opening 211, the feeding channel 220 is communicated with the feeding opening 211, the feeding channel 220 comprises two parallel conveyor belts 221 and a bottom plate 222, the bottom plate 222 is arranged below the conveyor belts 221, the bottom plate 222 is arranged between the two conveyor belts 221, the plane where the conveyor belts 221 are located is perpendicular to the plane where the bottom plate 222 is located, and at least one conveyor belt 221 is arranged to be tightly attached to the magnetic core 100;

specifically, the magnetic core 100 is placed in the feeding tray 210, the feeding tray 210 feeds the magnetic core 100 into the feeding channel 220, wherein at least one of the conveyor belts 221 is disposed close to the magnetic core 100, that is, the conveyor belt 221 drives the magnetic core 100 to roll when conveying, so as to drive the magnetic core 100 to move in the feeding channel 220, and the feeding speed of the magnetic core 100 in the feeding channel 220 is adjusted by adjusting the conveying speed of the conveyor belt 221.

It should be noted that, the two conveyor belts 221 do not necessarily need to be operated completely, when the conveying efficiency of the magnetic core 100 is sufficient, only one conveyor belt 221 may be used, and the conveying direction of the conveyor belt 221 needs to be consistent with the moving direction of the magnetic core 100; when it is required to increase the transmission efficiency of the magnetic core 100, the two conveyor belts 221 operate simultaneously, the transmission directions of the two conveyor belts 221 need to be opposite, and the rotation speed of the conveyor belt 221 corresponding to the movement direction of the magnetic core 100 needs to be larger.

The present application uses two conveyor belts 221 as the side walls of the conveying channel, rather than using the conventional method of placing objects on the conveyor belts 221 for conveying, mainly considering the following points:

firstly, the magnetic core 100 is vertically placed, so that the subsequent drilling operation on the magnetic core 100 from top to bottom is facilitated, when the magnetic core 100 is in a horizontal state, the magnetic core 100 is easy to roll, and when the magnetic core is drilled, the situation of drilling deviation is easy to occur;

secondly, two conveyor belts 221 are adopted to convey the magnetic cores 100, in order to enable the magnetic cores 100 to be compactly arranged, the conveyor belt 221 on one side is respectively started, the conveyor belt 221 on the other side is closed, the magnetic cores 100 tightly attached to the conveyor belts 221 move in the conveying direction, and one conveyor belt 221 is intermittently started and closed, so that the magnetic cores 100 can be compactly arranged, the processing continuity of the magnetic cores 100 is effectively guaranteed, and the processing efficiency is improved.

When the magnetic core 100 enters the feeding channel 220 from the feeding tray 210, the magnetic core 100 still keeps a vertical state, and this technical effect is achieved by the prior art that can be known by those skilled in the art, such as: the feeding opening 211 is horizontal to the bottom plate 222, when the feeding tray 210 rotates, the magnetic core 100 behind the feeding opening 211 pushes the magnetic core 100 at the feeding opening 211 to enter the feeding channel 220, and because the distance between the magnetic cores 100 is small, the magnetic cores 100 do not incline, and the magnetic cores 100 can keep a vertical state; there are other technical implementation schemes, which are not described herein.

The positioning mechanism 300 comprises a positioning frame 310 and a clamping mechanism 320, the positioning frame 310 is arranged at the tail end of the feeding channel 220, the positioning frame 310 comprises a placing table 311, the placing table 311 and the bottom plate 222 are arranged on the same horizontal plane, the placing table 311 is used for placing the magnetic core 100, and a chip leakage hole 3111 is formed in the bottom of the placing table 311; the clamping mechanism 320 is arranged on one side of the positioning frame 310, the clamping mechanism 320 comprises a workbench 321, a lifting cylinder 322, a rotating cylinder 323, a push-pull cylinder 324 and a pneumatic clamping jaw 325, the lifting cylinder 322 is arranged on the workbench 321, a lifting rod of the lifting cylinder 322 is arranged perpendicular to the workbench 321, the rotating cylinder 323 is connected with the lifting rod, a rotating shaft of the rotating cylinder 323 is arranged in a straight line with the lifting rod, the push-pull cylinder 324 is connected with the rotating shaft, a push-pull rod of the push-pull cylinder 324 is arranged perpendicular to the rotating shaft, the pneumatic clamping jaw 325 is connected with the push-pull rod, and a clamping portion 3251 of the pneumatic clamping jaw 325 is used for clamping the magnetic core 100;

specifically, after the feeding mechanism 200 conveys the magnetic core 100 to the placing table 311, the rotating cylinder 323 rotates the rotating shaft, so that the push-pull rod of the push-pull cylinder 324 faces the magnetic core 100, the push-pull cylinder 324 pushes the pneumatic clamping jaw 325, so that the clamping portion 3251 surrounds the magnetic core 100, the lifting cylinder 322 lifts the lifting rod, so that the rotating cylinder 323, the push-pull cylinder 324 and the pneumatic clamping jaw 325 lift, so that the clamping portion 3251 is located at a proper position of the magnetic core 100, and the clamping portion 3251 clamps the magnetic core 100 again, so that the magnetic core 100 is fixed, thereby facilitating a subsequent drilling and polishing operation.

The clamp portion 3251 may be two thin semicircular pieces, and the magnetic core 100 can be restricted from moving by folding the semicircular pieces so that the magnetic core 100 is surrounded by the two semicircular pieces.

The punching mechanism 400 comprises a fixing frame 410, a hydraulic lifting rod 420, a rotating disc 430 and a drill 440, wherein the fixing frame 410 is arranged above the positioning frame 310, the hydraulic lifting rod 420 is vertically arranged, the rotating disc 430 is horizontally arranged, the hydraulic lifting rod 420 is arranged below the fixing frame 410, one end of the hydraulic lifting rod 420 is connected with the fixing frame 410, the other end of the hydraulic lifting rod 420 is connected with the center of the rotating disc 430, the drill 440 comprises a drill rod 441, and one end of the drill rod 441, which is used for drilling the magnetic core 100, is provided with a drill;

specifically, the rotating disc 430 rotates, so that the drill 440 faces the magnetic core 100, and the hydraulic lifting rod 420 descends, so that the rotating disc 430 descends, and the drill 440 is driven to drill the magnetic core 100; after the drilling operation is completed, the hydraulic lift lever 420 is raised, so that the rotary disk 430 is raised, and then a drilling and polishing operation for the next magnetic core 100 is performed.

In order to enable the drill 440 or the sander 450 to face the magnetic core 100, two position sensors may be disposed on the rotating disc 430 and the placing table 311, respectively, and the two position sensors face each other, and when the drill 440 or the sander 450 faces the magnetic core 100, the two opposite position sensors can sense each other, one of the position sensors is electrically connected to the driving mechanism of the rotating disc 430, and when the two position sensors sense each other, one of the position sensors controls the driving mechanism of the rotating disc 430 to stop driving, at this time, the drill 440 or the sander 450 can face the magnetic core 100.

The rotation driving mechanism of the rotating disk 430 may use a motor or an air cylinder, which belongs to the technology known to those skilled in the art and will not be described herein.

The cleaning mechanism 500 comprises a high-pressure air gun 510, the high-pressure air gun 510 is fixed on the rotating disc 430, the gun head of the high-pressure air gun 510 is arranged right opposite to the placing table 311, and the high-pressure air gun 510 is connected with an air compressor through an air pipe.

Specifically, an air compressor injects high-pressure air into the high-pressure air gun 510, and the high-pressure air gun 510 performs air injection cleaning on the magnetic core 100; the rotating disk 430 rotates to drive the high-pressure air gun 510 to rotate, the high-pressure air gun 510 can blow air to the magnetic core 100 from the periphery so as to blow away the scraps on the magnetic core 100, the scraps outside the magnetic core 100 are directly blown away from the placing table 311, and the scraps in the magnetic core 100 hole are blown away from the scrap leakage hole 3111. In the operation flow of drilling and polishing, the rotating disc 430 needs to rotate twice, the high-pressure air gun 510 is fixed on the rotating disc 430, and the high-pressure air gun 510 can perform two cleaning operations on the magnetic core 100 after the drilling and polishing operations, so that the product quality is improved.

In one embodiment, the clearance hole 3111 has a diameter smaller than a diameter of the magnetic core 100.

Specifically, the chip leakage hole 3111 is used to leak out chips in the hole of the magnetic core 100, and the diameter of the chip leakage hole 3111 is smaller than the diameter of the magnetic core 100, so that the magnetic core 100 cannot fall out of the chip leakage hole 3111.

In this embodiment, in order to collect and clean the sweeps, the scrap collecting frame is further included, the scrap collecting frame is provided with an opening with a large top and a small bottom, the opening is arranged below the positioning frame 310, the scrap leaking hole 3111 penetrates through the positioning frame 310, the sweeps in the holes of the magnetic core 100 are blown into the collecting frame by the high-pressure air gun 510 directly from the scrap leaking hole 3111, and the sweeps outside the magnetic core 100 can be blown off from the placing table 311 by the high-pressure air gun 510 and fall into the scrap collecting frame.

In one embodiment, in order to protect the staff from the waste debris entering the eyes or the nose and mouth, the punching device further comprises a protective cover which covers the magnetic material punching device 10, and the protective cover can be a plastic curtain or a cloth curtain.

In an embodiment, please refer to fig. 3, further comprising a material receiving frame 600, wherein the material receiving frame 600 is disposed adjacent to the working platform 321, and the material receiving frame 600 is disposed below one end of the clamping bar, at which the clamping groove is disposed.

Specifically, after the drilling and polishing operation is completed, the pneumatic clamping jaw 325 clamps the magnetic core 100, the rotating cylinder 323 rotates to enable the position of the pneumatic clamping jaw 325 to be located above the material receiving frame 600, the pneumatic clamping jaw 325 loosens the magnetic core 100, and the magnetic core 100 falls into the material receiving frame 600 under the action of gravity, so that the material receiving of the processed magnetic core 100 is completed.

In one embodiment, the punching mechanism 400 further comprises a sander 450, the drill 440 and the sander 450 are oppositely disposed at two ends of the symmetry axis of the rotating disc 430, the sander 450 comprises a sanding rod 442, and a sanding head is disposed at one end of the sander 450 for sanding the magnetic core 100.

Specifically, after the drilling is completed, the hydraulic lifting rod 420 is lifted, so that the rotating disc 430 is lifted, the rotating disc 430 rotates, the sander 450 is opposite to the magnetic core 100, and the hydraulic lifting rod 420 is lowered, so that the rotating disc 430 is lowered, and the sander 450 is driven to perform a sanding operation on the magnetic core 100; after the grinding operation is completed, the hydraulic lift lever 420 is raised, so that the rotary disk 430 is raised, and then a drilling grinding operation for the next magnetic core 100 is performed.

In one embodiment, referring to fig. 4 and 5, the device further includes an auxiliary mechanism 700, the auxiliary mechanism 700 includes a supporting mechanism 710 and a limiting mechanism 720,

the supporting mechanism 710 includes a supporting bracket 711 and a supporting plate 712, the supporting bracket 711 is disposed above the placing table 311, the supporting plate 712 is disposed above the supporting bracket 711, a through hole 7121 is disposed on the supporting plate 712, and when the magnetic core 100 is placed on the placing table 311, the through hole 7121 is disposed opposite to the magnetic core 100;

the limiting mechanism 720 comprises a limiting baffle 721, an elastic sleeve 722 and two guide rails 723, two sliding holes are arranged on the rotating disk 430, the two sliding holes are arranged opposite to the center of the rotating disk 430, the guide rails 723 are vertically arranged, the limiting baffle 721 is arranged in parallel with the rotating disk 430, one end of the guide rail 723 is fixed on the limiting baffle 721, the other end of the guide rail 723 is slidably arranged in the sliding holes, and the elastic sleeve 722 is sleeved on the guide rail 723;

the limit baffle 721 is provided with a first alignment hole 7211 and a second alignment hole 7212, the first alignment hole 7211 is arranged right opposite to the drill rod 441, and the second alignment hole 7212 is arranged right opposite to the grinding rod 442.

Specifically, when the hydraulic lifting rod 420 presses down the rotating disc 430, the limit baffle 721 is supported by the supporting plate 712, the rotating disc 430 slides down along the guide rail 723 and presses down the elastic sleeve 722, the sliding rail enables the rotating disc 430 to do lifting movement in the vertical direction without deviation, the drill rod 441 passes through the first aligning hole 7211 and then passes through the through hole 7121 to drill the magnetic core 100; the polishing rod 442 passes through the second alignment hole 7212 and then passes through the through hole 7121 to polish the magnetic core 100, and the elastic sleeve 722 can play a role in buffering the pressing of the rotating disk 430, so that the drilling or over-polishing of the magnetic core 100 by the drill 440 or the polisher 450 is avoided. The auxiliary mechanism 700 enables the drill rod 441 and the grinding rod 442 to vertically drill and grind the magnetic core 100, so that the occurrence rate of defective products is reduced, and the product quality is improved.

In this embodiment, the stopper 721 is formed with an annular aligning hole 7213, and the annular aligning hole 7213 communicates the first aligning hole 7211 and the second aligning hole 7212.

Specifically, in order to facilitate installation and processing, the annular aligning hole 7213 is formed in the limiting baffle 721, and when the annular aligning hole is installed, the drill rod 441 and the polishing rod 442 need only to be aligned simultaneously by using the annular aligning hole, and the installation is easy because the area of the annular aligning hole is larger than that of a single hole, and the installation is not needed to be aligned to the drill rod 441 by using the first aligning hole 7211, and the installation is performed in a manner that the second aligning hole 7212 is aligned to the polishing rod 442, so that the installation efficiency is improved. In addition, the area of the alignment hole, which is directly opposite to the drill rod 441 and the grinding rod 442, is increased, so that the fault tolerance of the limiting mechanism 720 is improved.

In one embodiment, in order to protect the magnetic core 100 and prevent the magnetic core 100 from being damaged due to excessive clamping force of the pneumatic clamping jaw 325, the clamping portion 3251 of the pneumatic clamping jaw 325 is provided with a soft rubber layer.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (9)

1. A magnetic material perforating device, comprising: the device comprises a magnetic core, a feeding mechanism, a positioning mechanism, a punching mechanism and a cleaning mechanism;

the magnetic core is of a cylindrical structure, the feeding mechanism comprises a feeding disc and a feeding channel, the magnetic core is vertically placed on the feeding disc, the feeding disc is provided with a feeding opening, the feeding channel is communicated with the feeding opening, the feeding channel comprises two parallel conveyor belts and a bottom plate, the bottom plate is arranged below the conveyor belts, the bottom plate is arranged between the two conveyor belts, the plane where the conveyor belts are located is perpendicular to the plane where the bottom plate is located, and at least one conveyor belt is arranged to be tightly attached to the magnetic core;

the positioning mechanism comprises a positioning frame and a clamping mechanism, the positioning frame is arranged at the tail end of the feeding channel and comprises a placing table, the placing table and the bottom plate are arranged on the same horizontal plane, the placing table is used for placing the magnetic core, and a chip leakage hole is formed in the bottom of the placing table; the clamping mechanism is arranged on one side of the positioning frame and comprises a workbench, a lifting cylinder, a rotating cylinder, a push-pull cylinder and a pneumatic clamping jaw, the lifting cylinder is arranged on the workbench, a lifting rod of the lifting cylinder is perpendicular to the workbench, the rotating cylinder is connected with the lifting rod, a rotating shaft of the rotating cylinder and the lifting rod are arranged in a straight line, the push-pull cylinder is connected with the rotating shaft, a push-pull rod of the push-pull cylinder is perpendicular to the rotating shaft, the pneumatic clamping jaw is connected with the push-pull rod, and a clamping part of the pneumatic clamping jaw is used for clamping the magnetic core;

the punching mechanism comprises a fixing frame, a hydraulic lifting rod, a rotating disc and a borer, the fixing frame is arranged above the positioning frame, the hydraulic lifting rod is vertically arranged, the rotating disc is horizontally arranged, the hydraulic lifting rod is arranged below the fixing frame, one end of the hydraulic lifting rod is connected with the fixing frame, the other end of the hydraulic lifting rod is connected with a disc center of the rotating disc, the borer comprises a drill rod, and one end, used for drilling the magnetic core, of the drill rod is provided with a drill bit;

the cleaning mechanism comprises a high-pressure air gun, the high-pressure air gun is fixed on the rotating disc, the gun head of the high-pressure air gun is opposite to the placing table, and the high-pressure air gun is connected with an air compressor through an air pipe.

2. The punching device for magnetic materials according to claim 1, wherein the diameter of the chip leakage hole is smaller than the diameter of the magnetic core.

3. The magnetic material perforating device as claimed in claim 2, further comprising a scrap collecting frame, wherein the scrap collecting frame is provided with an opening with a large top and a small bottom, the opening is arranged below the positioning frame, and the scrap leaking hole penetrates through the positioning frame.

4. The magnetic material perforating device as recited in claim 1 further comprising a protective cover covering the magnetic material perforating device.

5. The magnetic material punching apparatus according to claim 1, further comprising a receiving frame disposed adjacent to the table.

6. The punching device for the magnetic material according to claim 1, wherein the punching mechanism further comprises a sander, the puncher and the sander are oppositely arranged at two ends of the symmetry axis of the rotating disc, the sander comprises a sanding rod, and a sanding head is arranged at one end of the sander used for sanding the magnetic core.

7. The magnetic material punching device according to claim 6, further comprising an auxiliary mechanism including a holding mechanism and a limiting mechanism,

the bearing mechanism comprises a bearing bracket and a bearing plate, the bearing bracket is arranged above the placing table, the bearing plate is arranged above the bearing bracket, a through hole is formed in the bearing plate, and when the magnetic core is placed on the placing table, the through hole is over against the magnetic core;

the limiting mechanism comprises a limiting baffle, an elastic sleeve and two guide rails, two sliding holes are formed in the rotating disc, the two sliding holes are arranged opposite to the center of the rotating disc, the guide rails are vertically arranged, the limiting baffle and the rotating disc are arranged in parallel, one end of each guide rail is fixed on the limiting baffle, the other end of each guide rail penetrates through the corresponding sliding hole in a sliding mode, and the elastic sleeve is sleeved on the guide rails;

the limiting baffle is provided with a first alignment hole and a second alignment hole, the first alignment hole is over against the drill rod, and the second alignment hole is over against the grinding rod.

8. The magnetic material perforating device as claimed in claim 7, wherein the limiting baffle is provided with a circular alignment hole, and the circular alignment hole communicates with the first alignment hole and the second alignment hole.

9. The magnetic material perforating device as claimed in claim 1, wherein the clamping portion of the pneumatic clamping jaw is provided with a soft rubber layer.

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