CN112053844A - Automatic processing equipment for compression molding and conveying of magnetic core - Google Patents

Abstract

The invention discloses automatic processing equipment for compression molding and conveying of a magnetic core, which comprises a machine table and a workbench arranged in the machine table, wherein the workbench is connected with a magnetic core conveying belt, a molding device is arranged on the workbench, the magnetic core conveying belt comprises an inclined conveying belt and a vertical conveying belt connected with the bottom end of the inclined conveying belt, a supporting plate which is inclined downwards and is in clearance connection with the inclined conveying belt is arranged right in front of the vertical conveying belt, the bottom end of the supporting plate is connected with a horizontal conveying belt through a downward inclined connecting plate, an arc-shaped guide plate which is inclined downwards and is connected with the upper surface of the horizontal conveying belt is arranged on the supporting plate, and an arc-shaped transition plate which is bent inwards. According to the invention, the arc transition plate is arranged, so that automatic turnover work can be realized in the process of conveying the processed and molded green bodies from the vertical conveying belt to the connecting plate, a plurality of devices can be simultaneously controlled by one person, the production efficiency of the magnetic core is improved, and the labor intensity of workers and the production cost of the magnetic core are reduced.

Description

Automatic processing equipment for compression molding and conveying of magnetic core

Technical Field

The invention relates to the technical field of magnetic core production and processing equipment, in particular to automatic processing equipment for compression molding and conveying of a magnetic core.

Background

The magnetic core is a sintered magnetic metal oxide composed of various iron oxide mixtures, and is formed by pressing iron powder through a die and then sintering at a high temperature in a high-temperature sintering furnace protected by nitrogen. 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.

The production of the magnetic core mainly comprises the following steps: mixing raw materials, spraying and granulating, pressing, stacking and sintering. In the production process, a large amount of tiny burrs can be remained on the surface of the green body to be made, the green body can become a finished product blank for sintering after deburring treatment, the existing magnetic core deburring is usually carried out in an artificial mode, the manual deburring is low in efficiency, the deburring effect is not good, and the problems of low production efficiency of the magnetic core and poor product quality of the magnetic core are easily caused.

In addition, after the press forming of the partial green body formed after the green body pressing, the green body needs to be turned over so as to facilitate the processing and stacking of the next procedure, the turning-over processing of the current green body is mainly carried out in a manual operation mode, the full automation of the production process of the magnetic core cannot be realized, the time consumption of the whole process is extremely long, the labor intensity of workers is increased, the processing and production efficiency of the magnetic core is also reduced, and the production cost of the magnetic core is increased.

Therefore, it is desirable to provide a processing apparatus for magnetic core production that can realize full-automatic production and improve production efficiency.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: the defects of the prior art are overcome, and the automatic processing equipment for the magnetic core press forming and conveying is high in production efficiency and capable of realizing full-automatic processing production.

The technical scheme adopted by the invention for solving the technical problems is as follows: the utility model provides an automatic processing equipment for magnetic core press forming and transport, includes the board and locates the inside workstation of board, the workstation is connected with the magnetic core conveyer belt, and installs forming device on it, the magnetic core conveyer belt include the slope conveyer belt and with the vertical conveyer belt of the bottom connection of slope conveyer belt, the dead ahead of vertical conveyer belt is equipped with the downward sloping and rather than clearance connection's backup pad, the bottom of backup pad is connected with horizontal transport belt through the connecting plate of downward sloping, be equipped with downward sloping and bottom rather than surface connection's arc guide board in the backup pad, the arc guide board is equipped with the arc of inside lateral bending with the junction of connecting plate or backup pad and crosses the cab apron.

According to the invention, the arc transition plate is arranged, so that automatic turnover work can be realized in the process of conveying the processed and molded green body from the vertical conveying belt to the connecting plate, the problem of low working efficiency in manual turnover is avoided, a plurality of devices can be simultaneously operated by one person, the production efficiency of the magnetic core is greatly improved, and the labor intensity of workers and the production cost of the magnetic core are reduced.

Furthermore, a gap is reserved between the arc-shaped transition plate and the vertical conveying belt, so that smooth operation and transmission of the vertical conveying belt are guaranteed.

Further, the bilateral symmetry of the junction of slope conveyer belt and vertical conveyer belt is equipped with the mounting panel, backup pad, arc guide board and connecting plate all connect on the mounting panel.

Further, be connected with the support on the slope conveyer belt, install burring motor on the support, burring motor's output shaft has the brush dustcoat, the inside brush that is equipped with of brush dustcoat.

According to the invention, the hairbrush is arranged on the inclined conveying belt, so that burrs on the surface of the green body can be automatically removed when the processed and molded green body is conveyed to the hairbrush, and the working efficiency and the burr removing effect are improved.

Further, forming device includes mould and drive arrangement, the mould includes type, type and female type, female type is installed in the middle part of workstation, and is equipped with the shaping chamber in it, the type inserts the shaping intracavity from the bottom of female type down, drive arrangement is including the first driver that is used for driving type reciprocating motion from top to bottom and the first actuating mechanism that is used for driving type reciprocating motion from top to bottom.

Preferably, the first actuator is a pneumatic or hydraulic cylinder.

Further, first actuating mechanism include with board sliding connection's sliding block, the top of sliding block is installed and is used for driving its second driver at workstation top up-and-down reciprocating motion, and it with be equipped with guider between the type.

Preferably, the second actuator is a pneumatic or hydraulic cylinder.

Further, guider is including locating a pair of guide post on the workstation and locating the deflector between the guide post, deflector and guide post sliding connection, its bottom with the type of going up is connected, and its top with be equipped with the spliced pole between the sliding block, the inside of sliding block be equipped with the guiding hole that the guide post cooperateed and uses.

The upper die reciprocates up and down along the direction vertical to the workbench right above the female die by arranging the guide device, so that the phenomenon that the upper die cannot be smoothly inserted into the forming cavity of the female die due to the offset phenomenon in the up-down reciprocating motion process is avoided, and the processing quality of the magnetic core is improved.

Further, still be equipped with on the workstation and be used for the unburned bricks of machine-shaping along the length direction of workstation to the propelling movement of slope conveyer belt and be used for pushing the powder material to the pushing away charging mechanism in the matrix.

Furthermore, the material pushing and charging mechanism comprises a charging box and a second driving mechanism used for driving the charging box to reciprocate back and forth on the workbench, the bottom of the charging box is of an open structure, and the top of the charging box is also connected with a sliding rod in sliding connection with the top of the machine table.

Further, the second driving mechanism comprises a push plate, a connecting rod, a cam and a cam shaft, the push plate, the connecting rod and the cam shaft penetrate through the cam, the push plate is connected with an I-shaped push rod, a first cross rod of the I-shaped push rod is connected with the push plate, an annular groove is formed in a second cross rod of the I-shaped push rod, the top end of the connecting rod is clamped in the annular groove, the bottom end of the connecting rod is connected with a sleeve, a fixed column transversely penetrates through the sleeve, a movable rod is connected below the sleeve, two ends of the fixed column are connected to the machine table, a linkage column is arranged on one side of the movable rod and is in contact connection with the cam, and two ends of the cam.

Further, still be equipped with the fly leaf between workstation and the slope conveyer belt, the top and the workstation swing joint of fly leaf, its bottom is set up in the top of slope conveyer belt.

Further, the bottom of the workbench is also connected with a third driver for driving the workbench to reciprocate up and down.

Preferably, the third actuator is a pneumatic or hydraulic cylinder.

The automatic processing equipment for the compression molding and conveying of the magnetic core has the beneficial effects that:

(1) the automatic turnover machine is convenient to operate, automatic turnover can be realized in the process of conveying the processed and molded green bodies to the connecting plate from the vertical conveying belt through the arc transition plate, the problem of low working efficiency in manual turnover is solved, a plurality of devices can be simultaneously controlled by one person, the production efficiency of the magnetic core is greatly improved, and the labor intensity of workers and the production cost of the magnetic core are reduced;

(2) according to the invention, the hairbrush is arranged on the inclined conveying belt, so that burrs on the surface of the green body can be automatically removed when the processed and molded green body is conveyed to the hairbrush, and the working efficiency and the burr removing effect are improved.

Drawings

FIG. 1 is a schematic perspective view of an automated processing apparatus for magnetic core compression molding and conveying according to the present invention;

FIG. 2 is an enlarged view of the point A in FIG. 1;

FIG. 3 is an enlarged view of the point B in FIG. 1;

FIG. 4 is an enlarged view of the brush of FIG. 1;

FIG. 5 is a schematic perspective view of an alternative embodiment of an automated magnetic core compression molding and delivery apparatus of the present invention;

fig. 6-is an enlarged view at C in fig. 5.

The above reference numerals: 1-top plate, 2-machine column, 3-workbench, 4-inclined conveyor belt, 5-vertical conveyor belt, 6-movable plate, 7-striker plate, 8-baffle plate, 9-mounting plate, 10-arc transition plate, 11-support plate, 12-arc guide plate, 13-connecting plate, 14-horizontal conveyor belt, 15-green body, 16-bracket, 17-deburring motor, 18-brush housing, 19-burr, 20-upper form, 21-female form, 22-first driver, 23-sliding block, 24-second driver, 25-guide column, 26-guide plate, 27-connecting column, 28-charging box, 29-third driver, 30-connecting ring, 31-movable shaft, 32-push plate, 33-connecting rod, 34-cam, 35-cam shaft, 36-first cross rod, 37-second cross rod, 38-sleeve, 39-fixed column, 40-movable rod, 41-linkage column, 42-bearing seat and 43-sliding rod.

Detailed Description

The invention is further illustrated with reference to the following figures and examples, which are not intended to limit the scope of the invention in any way.

Example 1

The utility model provides an automatic processing equipment for magnetic core press forming and transport, includes the board, the board includes roof 1 and locates four machine columns 2 of 1 four corners below of roof, workstation 3 is located between four machine columns 2, and its front end is connected with the magnetic core conveyer belt, and installs forming device among them to forming device can divide into front end portion and back end portion with workstation 3 as the boundary line, and the front end portion of workstation 3 is the downward sloping setting, and the angle of slope is 5-10, is 5 in the embodiment, is convenient for with 15 propelling movements of unburned bricks and convey to the magnetic core conveyer belt.

The bottom of magnetic core conveyer belt is equipped with the magnetic substance, and the magnetic substance is used for adsorbing the unburned bricks 15 after the machine-shaping in the transportation in the upper surface of magnetic core conveyer belt, the magnetic core conveyer belt includes the slope conveyer belt 4 that the slope set up and the vertical conveyer belt 5 of being connected with the bottom of slope conveyer belt 4 down, be equipped with fly leaf 6 between the top of slope conveyer belt 4 and the front end of workstation 3, the top and the 3 swing joint of workstation of fly leaf 6, the top of slope conveyer belt 4 is set up in its bottom.

The top of fly leaf 6 and workstation 3 swing joint's concrete structure does: a pair of connecting rings 30 is arranged on the side surface of the front end of the workbench 3, a movable shaft 31 penetrates through the movable plate 6, and two ends of the movable shaft 31 penetrate through the connecting rings 30. Because workstation 3 can the up-and-down motion at the operation in-process, through setting up fly leaf 6 with workstation 3 swing joint, be convenient for carry the unburned bricks 15 after the machine-shaping on workstation 3 to slope conveyer belt 4 on, avoid the risk that unburned bricks 15 dropped when workstation 3 moves from top to bottom, guaranteed the smooth transmission of unburned bricks 15.

The workbench 3 and the movable plate 6 are respectively provided with a pair of material blocking plates 7, the material blocking plates 7 are arranged to enable the green body 15 to be always positioned between the pair of material blocking plates 7 in the conveying process, the phenomenon that the conveying order of the green body 15 is disordered due to the fact that the green body 15 is dispersed to the outer sides of the material blocking plates 7 in the up-and-down movement process of the workbench 3 and the movable plate 6 is avoided, and the conveying efficiency of the green body 15 is improved; the left and right sides of workstation 3 and fly leaf 6 all is equipped with baffle 8, and the risk that unburned bricks 15 dropped to the ground can be avoided in the setting of baffle 8.

The bilateral symmetry of the junction of slope conveyer belt 4 and vertical conveyer belt 5 is equipped with mounting panel 9, mounting panel 9 passes through bolted connection with slope conveyer belt 4 and fixes, and the side that is located the left mounting panel 9 of vertical conveyer belt 5 is connected with the arc and crosses cab apron 10, and the side that is located mounting panel 9 on vertical conveyer belt 5 right side is connected with backup pad 11 and the arc guide board 12 that all slopes down and set up.

The utility model discloses a vertical conveyer belt 5, including backup pad 11, connecting plate 13, arc guide board 12, mounting panel 9, cab apron, backup pad 11 is located vertical conveyer belt 5's dead ahead, and its bottom is connected with horizontal conveyer belt 14 through the connecting plate 13 of downward sloping, and leaves the clearance between its and vertical conveyer belt 5 to guarantee vertical conveyer belt 5's smooth operation, arc guide board 12 locates backup pad 11 top, and the upper surface of its bottom and backup pad 11 is connected, and its top is connected with mounting panel 9, the arc crosses cab apron 10 and locates the junction of arc guide board 12 and connecting plate 13, and it is crooked to the inboard, the arc crosses and leaves the space between cab apron 10 and the vertical.

When the green compact 15 is conveyed to the arc guide plate 12, the side surface of the green compact 15 is in contact with the arc guide plate 12; when the green body 15 is continuously conveyed from the arc-shaped guide plate 12 to the connecting plate 13, the arc-shaped transition plate 10 can enable the green body 15 to automatically turn over, so that the top surface of the green body 15 is contacted with the connecting plate 13 after the green body 15 is conveyed to the connecting plate 13; and when unburned bricks 15 continue to be conveyed to the horizontal conveying belt, the top surface of the unburned bricks 15 contacts with the horizontal conveying belt, the phenomenon that conveying of the unburned bricks 15 is unstable due to the fact that the side surfaces of the unburned bricks 15 contact with the connecting plate 13 and the horizontal conveying belt is avoided, conveying speed of the unburned bricks 15 and stacking of the unburned bricks 15 in subsequent processes are affected, the problem that working efficiency is low when manual turning-over is adopted is avoided, multiple devices can be controlled simultaneously by one person, production efficiency of the magnetic core is greatly improved, and labor intensity of workers and production cost of the magnetic core are reduced.

Be connected with support 16 on the slope conveyer belt 4, install burring 19 motor 17 on the support 16, the output shaft of burring 19 motor 17 has brush dustcoat 18, the inside brush that is equipped with of brush dustcoat 18 makes the brush rotate under the drive of burring 19 motor 17 and realizes the 19 processing work of burring to 15 surfaces of unburned bricks.

According to the invention, the hairbrush is arranged on the inclined conveying belt 4, so that burrs 19 on the surface of the green body 15 can be automatically removed when the processed and molded green body 15 is conveyed to the hairbrush, and the working efficiency and the burr 19 removing effect are improved.

Forming device includes mould and drive arrangement, the mould includes type 20, down type and female type 21, female type 21 is installed in the middle part of workstation 3, and is equipped with the shaping chamber in it, the type is followed female type 21's bottom and is inserted the shaping intracavity down, drive arrangement is including being used for driving down type reciprocating motion's first driver 22 and being used for driving down type reciprocating motion's first actuating mechanism down, first driver 22 is the pneumatic cylinder, and the top of the telescopic link of pneumatic cylinder is connected with the bottom of type down, and the telescopic motion through the telescopic link of pneumatic cylinder drives the type down and pushes out the shaping chamber with unburned bricks 15 at the inside upward movement of female type 21. The mold in the invention can be a mold for manufacturing a magnetic core in the prior art, for example, a mold for processing an inductance magnetic core disclosed in patent application No. CN 201720241262.6.

First actuating mechanism include with board sliding connection's sliding block 23 specifically is: the machine column 2 positioned at two sides of the sliding block 23 is provided with a sliding groove, and two sides of the sliding block 23 slide up and down in the sliding groove. The second driver 24 that is used for driving its reciprocating motion about 3 tops of workstation is installed at sliding block 23's top, second driver 24 is the pneumatic cylinder, and the bottom and the sliding block 23 of the telescopic link of pneumatic cylinder are connected, and the concertina movement of the telescopic link through the pneumatic cylinder drives sliding block 23 reciprocating motion about to drive type 20 reciprocating motion about going up.

The sliding block 23 with be equipped with guider between the last type 20, guider including locate a pair of guide post 25 on the workstation 3 with transversely locate between the guide post 25 and with guide post 25 sliding connection's deflector 26, the bottom of deflector 26 with last type 20 is connected, and its top with be equipped with spliced pole 27 between the sliding block 23, the inside of sliding block 23 be equipped with the guiding hole that the guide post 25 cooperateed and uses, at sliding block 23 downstream process, the guide post 25 can insert in the guiding hole.

According to the invention, the upper die 20 reciprocates up and down along the direction vertical to the workbench 3 right above the female die 21 by arranging the guide device, so that the phenomenon that the upper die 20 cannot be smoothly inserted into the forming cavity of the female die 21 due to the offset phenomenon in the up-and-down reciprocating process is avoided, and the processing quality and the processing precision of the magnetic core are improved.

The workbench 3 is also provided with a material pushing and charging mechanism which can be used for pushing the green body 15 positioned at the female die 21 to the inclined conveying belt 4 along the length direction of the workbench 3 and pushing the powder material into the female die 21.

The material pushing and charging mechanism comprises a charging box 28 and a second driving mechanism for driving the charging box 28 to reciprocate back and forth on the workbench 3, the bottom of the charging box 28 is of an open structure, and the top of the charging box 28 is also connected with a sliding rod 43 which is in sliding connection with the top plate 1, specifically: the top of the sliding rod is provided with a sliding groove, and the sliding rod 43 slides up and down in the sliding groove. The slide bars 43 are arranged to maintain the path of the reciprocating movement of the cartridge 28 back and forth to prevent the cartridge 28 from shifting during movement.

The second driving mechanism comprises a push plate 32, a connecting rod 33, a cam 34 and a cam shaft 35, the push plate 32 is arranged on two side surfaces of the charging box 28, the cam shaft 35 is arranged on the cam 34 in a penetrating manner, the push plate 32 is connected with an I-shaped push rod, a first cross rod 36 of the I-shaped push rod is connected with the push plate 32, a second cross rod 37 of the I-shaped push rod is provided with an annular groove, the top end of the connecting rod 33 is clamped in the annular groove, the bottom end of the connecting rod 33 is connected with a sleeve 38, a fixed column 39 transversely penetrates through the sleeve 38, a movable rod 40 is connected below the sleeve 38, two ends of the fixed column 39 are connected to the stand 2, one side of the movable rod 40 is provided with a linkage column 41, the linkage column 41 is in contact connection with the cam 34, two ends of the cam shaft 35 are arranged on the stand 2 through a bearing seat 42, the cam, which in turn drives the sleeve 38 to rotate back and forth, which in turn drives the linkage back and forth, which ultimately drives the push rod to move the cartridge 28 back and forth.

The bottom of workstation 3 still is connected with the third driver 29 that is used for driving up-and-down reciprocating motion, third driver 29 is the pneumatic cylinder, and the top of the telescopic link of pneumatic cylinder is connected with workstation 3, and the telescopic motion through the telescopic link of pneumatic cylinder drives workstation 3 up-and-down reciprocating motion.

The invention relates to a working principle and a using method of automatic processing equipment for compression molding and conveying of a magnetic core, which comprises the following steps:

when the invention works, the second driver 24 drives the sliding block 23 to move downwards to drive the upper die 20 to move downwards and insert into the forming cavity of the female die 21, and powder is processed and formed into a green body 15 in the forming cavity under the opposite extrusion of the upper die 20 and the lower die; the second driver 24 drives the slide block 23 to move upwards to drive the upper mold 20 to move upwards so as to separate the upper mold 20 from the female mold 21, the first driver 22 at the bottom of the lower mold drives the lower mold to move upwards so as to eject the prepared green body 15 upwards from the forming cavity, and the third driver 29 drives the workbench 3 to move downwards so as to expose the green body 15 on the workbench 3;

then, the cam 34 drives the push rod to push the charging box 28 forwards, so that the charging box 28 moves on the workbench 3 towards the green body 15 to push the green body 15 towards the magnetic core conveyer belt, and the powder positioned between the workbench 3 and the inside of the charging box 28 is pushed to the female die 21, so that the powder directly falls into the forming cavity of the female die 21 from the bottom of the charging box 28, and meanwhile, the third driver 29 drives the workbench 3 to move upwards for resetting; then the cam 34 drives the push rod to pull the cartridge 28 backwards to reset the cartridge 28 backwards, and the operation process is repeated after resetting;

the conveying process after the green body 15 is manufactured is as follows: when the charging box 28 moves forward to push the green body 15, the green body 15 passes through the movable plate 6, the inclined conveyor belt 4 and the vertical conveyor belt 5 from the workbench 3 in sequence, is conveyed to the arc-shaped guide plate 12, is conveyed to the horizontal conveyor belt 14 from the connecting plate 13 after being subjected to flanging treatment by the arc-shaped transition plate 10, and then enters the next process.

It will be further understood that the terms "first," "second," and the like, are used herein to describe various elements, but these elements should not be limited by these terms. These terms are only used to distinguish one element from another.

As used herein, the terms "upper," "lower," "left," "right," and the like are used for convenience of description based on the orientation as shown in the figures of the drawings, which may vary from one actual device to another depending on the manner in which the device is arranged.

Although the present invention has been described with reference to a preferred embodiment, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. The utility model provides an automated processing equipment for magnetic core compression molding and transport, includes the board and locates the inside workstation of board, the workstation is connected with the magnetic core conveyer belt, and installs forming device on it, the vertical conveyer belt that the magnetic core conveyer belt is connected including slope conveyer belt and with the bottom of slope conveyer belt, its characterized in that: the dead ahead of vertical conveyer belt is equipped with the downward sloping and rather than the backup pad of gap junction, the bottom of backup pad is connected with horizontal conveyer belt through the connecting plate of downward sloping, and is equipped with downward sloping and bottom rather than surface connection's arc guide board on it, the arc guide board is equipped with the arc of inside side bending with the junction of connecting plate or backup pad and crosses the cab apron.

2. An automated manufacturing apparatus for compression molding and transporting a magnetic core as claimed in claim 1, wherein: the bilateral symmetry of the junction of slope conveyer belt and vertical conveyer belt is equipped with the mounting panel, backup pad, arc guide board and connecting plate all connect on the mounting panel.

3. An automated manufacturing apparatus for compression molding and transporting a magnetic core as claimed in claim 1, wherein: the inclined conveying belt is connected with a support, a deburring motor is installed on the support, an output shaft of the deburring motor is connected with a brush outer cover, and a brush is arranged in the brush outer cover.

4. An automated manufacturing apparatus for compression molding and transporting a magnetic core as claimed in claim 1, wherein: the forming device comprises a die and a driving device, the die comprises an upper die, a lower die and a female die, the female die is installed at the middle part of the workbench, a forming cavity is formed in the female die, the lower die is inserted into the forming cavity from the bottom of the female die, and the driving device comprises a first driver used for driving the lower die to reciprocate up and down and a first driving mechanism used for driving the lower die to reciprocate up and down.

5. An automated manufacturing apparatus for magnetic core compression molding and delivery as recited in claim 4, wherein: first actuating mechanism include with board sliding connection's sliding block, the top of sliding block is installed and is used for driving its second driver at workstation top up-and-down reciprocating motion, and it with be equipped with guider between the type.

6. An automated manufacturing apparatus for compression molding and transporting a magnetic core according to claim 5, wherein: the guiding device comprises a pair of guide posts arranged on the workbench and a guide plate arranged between the guide posts, the guide plate is connected with the guide posts in a sliding mode, the bottom of the guide plate is connected with the upper die, the top of the guide plate is connected with the connecting post arranged between the sliding blocks, and guide holes matched with the guide posts for use are formed in the sliding blocks.

7. An automated manufacturing apparatus for compression molding and transporting a magnetic core as claimed in claim 1, wherein: the working table is also provided with a material pushing and loading mechanism which is used for pushing the processed and molded green body to the inclined conveying belt along the length direction of the working table and pushing the powder material into the female die.

8. An automated manufacturing apparatus for compression molding and transporting a magnetic core according to claim 7, wherein: the material pushing and charging mechanism comprises a charging box and a second driving mechanism used for driving the charging box to reciprocate back and forth on the workbench, the bottom of the charging box is of an open structure, and the top of the charging box is also connected with a sliding rod in sliding connection with the top of the machine table.

9. An automated manufacturing apparatus for compression molding and transporting a magnetic core as claimed in claim 1, wherein: still be equipped with the fly leaf between workstation and the slope conveyer belt, the top and the workstation swing joint of fly leaf, the top of slope conveyer belt is set up to its bottom.

10. An automated manufacturing apparatus for compression molding and transporting a magnetic core as claimed in claim 1, wherein: and the bottom of the workbench is also connected with a third driver for driving the workbench to reciprocate up and down.

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