CN110136950B - Processing technology of composite soft magnetic material - Google Patents

Abstract

The invention discloses a processing technology of a composite soft magnetic material, which comprises a processing main body, wherein a processing area is arranged at the position of the upper left side of the processing main body, a slotting device is arranged at the upper side of the processing area, a material pushing chute is arranged at the right side of the processing area, the left end of the material pushing chute is communicated with the processing area, a feeding box body with the bottom end communicated with the material pushing chute is fixedly arranged on the top end surface of the processing main body positioned at the right side of the processing area, a composite soft magnetic material substrate is arranged in the feeding box body, and the processing technology further comprises a material pushing control mechanism, a positioning linkage mechanism and a composite soft magnetic material discharge control mechanism which are arranged in the processing main body.

Description

Processing technology of composite soft magnetic material

Technical Field

The invention relates to the technical field of composite soft magnetic materials, in particular to a processing technology of a composite soft magnetic material.

Background

The composite soft magnetic material is a composite material with a soft magnetic function, which is formed by compounding soft magnetic ferrite and a high polymer matrix, the composite soft magnetic material is usually required to be made into a flat rectangle with a standard size, and batch grooving work is required in the use process of the composite soft magnetic material. The conventional composite soft magnetic material slotting device usually needs manual work to invest a single piece, is low in working efficiency, high in operation risk, needs to be improved, is complex in fixed mounting steps, increases the workload of workers, and is low in service efficiency of the composite soft magnetic material slotting device.

Disclosure of Invention

The invention aims to provide a processing technology of a composite soft magnetic material, which is used for overcoming the defects in the prior art.

The processing technology of the composite soft magnetic material comprises a processing main body, wherein a processing area is arranged at the position of the upper left side of the processing main body, a slotting device is arranged at the upper side of the processing area, a material pushing chute is arranged at the right side of the processing area, the left end of the material pushing chute is communicated with the processing area, a feeding box body with the bottom end communicated with the material pushing chute is fixedly arranged on the top end surface of the processing main body at the right side of the processing area, a composite soft magnetic material substrate is arranged in the feeding box body, and the processing technology further comprises a material pushing control mechanism, a positioning linkage mechanism and a composite soft magnetic material discharging control mechanism which are arranged in the processing main body;

wherein the material pushing control mechanism comprises a first cavity arranged on the right side of the material pushing chute and a second cavity which penetrates through the first cavity and extends left and right, the left end of the second cavity is fixedly provided with a right end of the material pushing chute which is communicated with the right end of the material pushing chute, the material pushing chute is connected with a pushing head in a sliding fit manner, the first cavity is connected with an internal thread rotating sleeve piece in a rotating fit manner, the outer surface of the internal thread rotating sleeve piece is fixedly provided with a first cone pulley, the internal thread rotating sleeve piece is connected with a first screw rod extending left and right in a matching manner, the left end of the first screw rod extends into the material pushing chute and is fixedly connected with the right end of the pushing head in a matching manner, the right end of the first screw rod is fixedly provided with a limiting slide block positioned in the second cavity on the right side of the first cavity, and the, a first rotating shaft is connected between the third cavity and the first cavity in a rotating fit manner, a second cone pulley which is positioned in the first cavity and is in meshed connection with the first cone pulley is fixedly arranged at the tail end of the top of the first rotating shaft, and a third cone pulley which is positioned in the third cavity is fixedly arranged at the tail end of the bottom of the first rotating shaft;

wherein, the positioning linkage mechanism comprises a guide chute communicated with and arranged in the end wall at the bottom of the processing area and a first chute arranged at the right side of the guide chute, the guide chute is connected with a positioning guide slide block in a sliding fit manner, a first rack is fixedly arranged in the end surface at the right side of the positioning guide slide block, a first slide block is connected with the first chute in a sliding fit manner, a second rack is fixedly arranged in the end surface at the left side of the first slide block, a first motor is fixedly arranged in the end surface at the bottom of the first slide block, the tail end at the bottom of the first motor is connected with a fourth cone pulley extending out of the end surface at the bottom of the first slide block in a dynamic manner, a first connecting groove is communicated with the first chute, the first connecting groove is connected with an adjusting gear engaged with the first rack and the second rack in a rotating fit manner, and the first chute is positioned at the left side of the third cavity, first spout with running fit is connected with the second pivot between the third cavity, the left side end of second pivot sets firmly to be located fifth cone pulley in the first spout, the right side end of second pivot sets firmly to be located in the third cavity and with the sixth cone pulley meshing is connected, be linked together in the right side end wall of first spout and be equipped with the second spout, sliding fit is connected with in the second spout with the second slider that first slider fixed fit is connected, second slider internal thread fit is connected with extends the second screw rod that sets up from top to bottom, the bottom end of second screw rod with inlay admittedly in the power fit of the second motor in the end wall of second spout bottom is connected.

According to the technical scheme, an inclined guide sliding plate is fixedly arranged on the end face of the left side of the machining main body and is located at the lower side of the machining area.

According to a further technical scheme, the composite soft magnetic material discharge control mechanism comprises a fourth cavity arranged on the upper side of the first sliding groove and a lifting slide block arranged in the fourth cavity in a sliding fit connection mode, the bottom end face of the lifting slide block is fixedly matched and connected with the top end of the first slide block, a sunken groove is formed in the top end face of the lifting slide block, a buffer slide block is arranged in the sunken groove, the bottom of the buffer slide block is connected with a buffer spring in a jacking fit mode, a movable groove with an upward opening is formed in the top end face of the buffer slide block, discharging rollers symmetrically arranged on the left side and the right side are connected in a rotating fit mode in the movable groove, a transmission belt wheel is fixedly arranged on the front end face of each discharging roller, a transmission belt is connected between the transmission belt wheels on the left side and the right side in a power fit mode, and the maximum circumcircle at, and a second communicating groove is communicated between the fourth cavity and the processing area, and the tail end of the rear side of the discharging roller on the left side is in power fit connection with a discharging motor fixedly embedded in the wall of the rear side end of the movable groove.

In a further technical scheme, an anti-skid top pressing block is fixedly arranged in the left end face of the pushing head.

Drawings

FIG. 1 is a schematic view showing an external structure of a process for manufacturing a composite soft magnetic material according to the present invention;

FIG. 2 is a schematic view showing the internal structure of a process for manufacturing a composite soft magnetic material according to the present invention;

fig. 3 is a partially enlarged view of a in fig. 2 according to the present invention.

Detailed Description

The present invention is described in detail below with reference to fig. 1-3.

Referring to fig. 1 to 3, the processing technology of a composite soft magnetic material according to the embodiment of the present invention includes a processing main body 6, a processing area 61 is disposed at an upper left side of the processing main body 6, a grooving device 7 is disposed at an upper side of the processing area 61, a material pushing chute 64 is disposed at a right side of the processing area 61, a left end of the material pushing chute 64 is communicated with the processing area 61, a feeding box 62 having a bottom end communicated with the material pushing chute 64 is fixedly disposed on a top end surface of the processing main body 6 located at the right side of the processing area 61, a composite soft magnetic material substrate 621 is disposed in the feeding box 62, and the processing technology further includes a material pushing control mechanism, a positioning linkage mechanism and a composite soft magnetic material discharge control mechanism disposed in the processing main body 6;

wherein the pushing control mechanism comprises a first cavity 65 arranged on the right side of the pushing chute 64 and a second cavity 651 penetrating through the first cavity 65 and extending left and right, the left end of the second cavity 651 is fixedly provided with a right end of the pushing chute 64 in a communicating manner, the pushing chute 64 is connected with a pushing head 641 in a sliding fit manner, the first cavity 65 is connected with an internal thread rotating sleeve 652 in a rotating fit manner, the outer surface of the internal thread rotating sleeve 652 is fixedly provided with a first cone pulley, the internal thread rotating sleeve 652 is connected with a first screw 654 extending left and right in a matching manner, the left end of the first screw 654 extends into the pushing chute 64 and is fixedly connected with the right end of the pushing head 641 in a matching manner, the right end of the first screw 654 is fixedly provided with a limit slider 655 positioned in the second cavity 651 on the right side of the first cavity 65, a third cavity 66 is arranged at the bottom of the first cavity 65, a first rotating shaft 661 is connected between the third cavity 66 and the first cavity 65 in a rotating fit manner, a second bevel wheel 662 which is positioned in the first cavity 65 and is in meshed connection with the first bevel wheel 653 is fixedly arranged at the tail end of the top of the first rotating shaft 661, and a third bevel wheel 663 which is positioned in the third cavity 66 is fixedly arranged at the tail end of the bottom of the first rotating shaft 661;

wherein, the positioning linkage mechanism comprises a guide chute 68 communicated with and arranged in the end wall of the bottom of the processing area 61 and a first chute 63 arranged on the right side of the guide chute 68, the guide chute 68 is connected with a positioning guide slide block 681 in a sliding fit manner, a first rack 682 is fixedly arranged in the right side end face of the positioning guide slide block 681, a first slide block 631 is connected with the first chute 63 in a sliding fit manner, a second rack 633 is fixedly arranged in the left side end face of the first slide block 631, a first motor 632 is fixedly arranged in the bottom end face of the first slide block 631, the bottom end of the first motor 632 is dynamically connected with a fourth cone wheel 634 extending out of the bottom end face of the first slide block 631, a first connecting groove 683 is communicated with the first chute 63, and an adjusting gear 684 engaged and connected with the first rack 682 and the second rack 633 is connected in the first connecting groove 683 in a rotating fit manner, the first sliding groove 63 is located at the left side of the third cavity 66, a second rotating shaft 664 is connected between the first sliding groove 63 and the third cavity 66 in a rotating fit manner, a fifth cone pulley 666 positioned in the first sliding groove 63 is fixedly arranged at the left end of the second rotating shaft 664, a sixth cone wheel 665 which is positioned in the third cavity 66 and is engaged with the third cone wheel 663 is fixedly arranged at the right end of the second rotating shaft 664, a second sliding groove 69 is communicated with the right end wall of the first sliding groove 63, a second sliding block 691 fixedly connected with the first sliding block 631 in a matching manner is connected in the second sliding groove 69 in a sliding manner, a second screw rod 693 which extends up and down is connected with the internal thread of the second slide block 691 in a matching way, the bottom end of the second screw 693 is connected with a second motor 692 fixedly embedded in the bottom end wall of the second chute 69 in a power-fit manner.

Beneficially or exemplarily, an inclined sliding guide plate 5 is fixedly arranged on the left end face of the processing body 6, and the inclined sliding guide plate 5 is located at the lower side position of the processing area 61, so that the processed composite soft magnetic material can be rapidly discharged, and uniform arrangement and placement work can be conveniently performed.

Beneficially or exemplarily, the composite soft magnetic material discharge control mechanism includes a fourth cavity 67 disposed on the upper side of the first sliding chute 63, and a lifting slider 671 slidably and fittingly connected to the fourth cavity 67, a bottom end surface of the lifting slider 671 is fixedly fittingly connected to a top end of the first slider 631, a sinking groove 6711 is disposed in a top end surface of the lifting slider 671, a buffering slider 672 is disposed in the sinking groove 6711, a buffering spring 6712 is press-fittingly connected to a bottom of the buffering slider 672, a movable groove 6721 having an upward opening is disposed in a top end surface of the buffering slider 672, the movable groove 6721 is rotatably fittingly connected to the symmetrically-arranged discharge rollers 6722, a driving pulley 6723 is fixedly disposed on a front end surface of the discharge roller 6722, and a driving belt 6742 is dynamically fittingly connected between the driving pulleys 6723 on the left and right sides, the biggest circumscribed circle in top of row material gyro wheel 6722 stretches out outside the top terminal surface of buffering slider 672, fourth cavity 67 with be linked together between the processing region 61 and be equipped with second intercommunication groove 670, the left side row material gyro wheel 6722 the rear side end with inlay admittedly in row material motor power fit connection in the end wall behind movable groove 6721 to realize that automatic control carries the compound soft magnetic material of accomplishing to leading oblique slide 5 on, and then improved work efficiency and alleviateed workman's the amount of labour.

Advantageously or exemplarily, an anti-slip jacking block 6411 is fixedly arranged in the left end face of the pushing head 641, so that the composite soft magnetic material is prevented from shifting due to slippage in the processes of pushing and jacking, and the processing stability is improved.

In the initial state, the push head 641 is located at the rightmost position in the push chute 64, and at this time, the push head 641 is furthest away from the position right below the feeding box 62, further, the composite soft magnetic material substrate 621 in the feeding box 62 falls into the pushing chute 64 on the left side of the pushing head 641, and at this time, the second slider 691 is located at the bottommost position in the second chute 69, and the second sliding block 691 drives the first sliding block 631 to extend into the first sliding groove 63 to the maximum extent, and the fourth cone pulley 634 at the bottom of the first slide 631 is engaged with the fifth cone pulley 666, and at this time, the first slider 631 drives the lifting slider 671 to be located at the bottommost position in the fourth cavity 67, and the second rack 633 on the first slide block 631 drives the adjusting gear 684 to rotate to the maximum extent, the adjusting gear 684 drives the first rack 682 and the top section of the positioning guide slider 681 to extend into the machining area 61 to the maximum extent;

when the composite soft magnetic material needs to be automatically controlled to be processed, the first motor 632 drives the fourth cone pulley 634 and the fifth cone pulley 666 to rotate, the second cone 662 drives the first cone 653 and the internal screw rotating sleeve 652 to rotate, so that the internal screw rotating sleeve 652 drives the first screw 654 and the pushing head 641 at the left end of the first screw 654 to slide toward the left side of the pushing chute 64, and then the composite soft magnetic material substrate 621 in the material pushing chute 64 is driven to push into the processing area 61 until the left end face of the composite soft magnetic material substrate 621 abuts against the positioning guide block 681 extending into the processing area 61, at this time, the anti-skid jacking block 6411 on the left end face of the pushing head 641 and the right end face of the composite soft magnetic material substrate 621 are always kept in a butting state, so that the composite soft magnetic material substrate 621 is stably positioned and mounted, and then the grooving operation is automatically controlled through the operation of the grooving device 7; after the grooving is completed, the second motor 692 controls the second screw 693 to rotate, the second screw 693 drives the second slider 691 to slide to the topmost position in the second sliding groove 69, at this time, the second rack 633 drives the adjusting gear 684 to rotate, the adjusting gear 684 drives the first rack 682 and the positioning slider 681 to completely slide into the guiding sliding groove 68, the second slider 691 drives the top section of the first slider 631 to maximally extend into the fourth cavity 67, the lifting slider 671 slides to the topmost position in the fourth cavity 67, at this time, the discharging roller 6722 in the lifting slider 671 abuts against the bottom end face of the composite soft magnetic material substrate 621, then the discharging roller 6722 on the left side is controlled to rotate by controlling the discharging motor, and the discharging roller 6722 on the right side is driven by the driving belt 6742 to rotate, so that the composite soft magnetic material substrate 621 is transferred to the inclined guiding sliding plate 5, finally, the second slider 691 is controlled to drive the first slider 631, the lifting slider 671 and the positioning guide slider 681 to return to the initial position through the reverse rotation of the second motor 692, and then the first motor 632 drives the fourth cone pulley 634 and the fifth cone pulley 666 to reversely rotate until the head 641 returns to the initial position, thereby conveniently realizing the subsequent processing work.

The invention has the beneficial effects that: the composite soft magnetic material substrate positioning and mounting device is simple in structure and convenient to operate, and the anti-skidding top pressing block on the left end face of the pushing head is always kept in a butting state with the right end face of the composite soft magnetic material substrate through the butting of the left end face of the composite soft magnetic material substrate and the positioning guide sliding block extending into a processing area, so that the stable positioning and mounting work of the composite soft magnetic material substrate is realized; through the bottom terminal surface looks butt of arranging material gyro wheel and compound soft magnetic material base plate in the lifting slide, then arrange material motor control left side through control and arrange the material gyro wheel and rotate to it rotates to drive the row material gyro wheel on right side by the drive belt, and then realizes discharging compound soft magnetic material base plate, and then makes things convenient for follow-up processing, has improved work efficiency greatly, has alleviateed workman's amount of labour.

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims (1)

1. The utility model provides a processing technology of compound soft magnetic material, includes the processing main part, the upper left side position department in the processing main part is equipped with the processing area territory, the processing area territory upside is equipped with the fluting device, the right side in processing area territory is equipped with and pushes away the material spout, the left side end that pushes away the material spout with the processing area territory is linked together the setting, is located the processing area territory right side set firmly the bottom on the terminal surface of the top of processing main part terminal with it is linked together the pay-off box body that sets up to push away the material spout, be equipped with compound soft magnetic:

the device also comprises a material pushing control mechanism, a positioning linkage mechanism and a composite soft magnetic material discharge control mechanism which are arranged in the processing main body;

wherein the material pushing control mechanism comprises a first cavity arranged on the right side of the material pushing chute and a second cavity which penetrates through the first cavity and extends left and right, the left end of the second cavity is fixedly provided with a right end of the material pushing chute which is communicated with the right end of the material pushing chute, the material pushing chute is connected with a pushing head in a sliding fit manner, the first cavity is connected with an internal thread rotating sleeve piece in a rotating fit manner, the outer surface of the internal thread rotating sleeve piece is fixedly provided with a first cone pulley, the internal thread rotating sleeve piece is connected with a first screw rod extending left and right in a matching manner, the left end of the first screw rod extends into the material pushing chute and is fixedly connected with the right end of the pushing head in a matching manner, the right end of the first screw rod is fixedly provided with a limiting slide block positioned in the second cavity on the right side of the first cavity, and the, a first rotating shaft is connected between the third cavity and the first cavity in a rotating fit manner, a second cone pulley which is positioned in the first cavity and is in meshed connection with the first cone pulley is fixedly arranged at the tail end of the top of the first rotating shaft, and a third cone pulley which is positioned in the third cavity is fixedly arranged at the tail end of the bottom of the first rotating shaft;

wherein, the positioning linkage mechanism comprises a guide chute communicated with and arranged in the end wall at the bottom of the processing area and a first chute arranged at the right side of the guide chute, the guide chute is connected with a positioning guide slide block in a sliding fit manner, a first rack is fixedly arranged in the end surface at the right side of the positioning guide slide block, a first slide block is connected with the first chute in a sliding fit manner, a second rack is fixedly arranged in the end surface at the left side of the first slide block, a first motor is fixedly arranged in the end surface at the bottom of the first slide block, the tail end at the bottom of the first motor is connected with a fourth cone pulley extending out of the end surface at the bottom of the first slide block in a dynamic manner, a first connecting groove is communicated with the first chute, the first connecting groove is connected with an adjusting gear engaged with the first rack and the second rack in a rotating fit manner, and the first chute is positioned at the left side of the third cavity, a second rotating shaft is connected between the first sliding groove and the third cavity in a rotating fit manner, a fifth cone pulley located in the first sliding groove is fixedly arranged at the tail end of the left side of the second rotating shaft, a sixth cone pulley located in the third cavity and meshed with the third cone pulley is fixedly arranged at the tail end of the right side of the second rotating shaft, a second sliding groove is communicated and arranged in the end wall of the right side of the first sliding groove, a second sliding block fixedly matched and connected with the first sliding block is connected in the second sliding groove in a sliding fit manner, a second screw rod extending up and down is connected in the second sliding block in a threaded fit manner, and the tail end of the bottom of the second screw rod is in power fit connection with a second motor fixedly embedded in the end wall of the bottom of the second sliding groove;

an inclined guide sliding plate is fixedly arranged on the left end face of the machining main body and is positioned at the lower side of the machining area;

the composite soft magnetic material discharge control mechanism comprises a fourth cavity arranged on the upper side of the first sliding groove and a lifting slide block arranged in the fourth cavity in a sliding fit connection mode, the bottom end face of the lifting slide block is fixedly matched and connected with the top end of the first slide block, a sunken groove is formed in the top end face of the lifting slide block, a buffer slide block is arranged in the sunken groove, the bottom of the buffer slide block is connected with a buffer spring in a jacking fit mode, a movable groove with an upward opening is formed in the top end face of the buffer slide block, discharging rollers symmetrically arranged on the left side and the right side are connected in a rotating fit mode in the movable groove, a transmission belt wheel is fixedly arranged on the front end face of each discharging roller, a transmission belt is connected between the transmission belt wheels on the left side and the right side in a power fit mode, and the maximum external circle of the, a second communicating groove is communicated between the fourth cavity and the processing area, and the rear end of the left discharging roller is in power fit connection with a discharging motor fixedly embedded in the wall of the rear end of the movable groove;

an anti-skid top pressing block is fixedly arranged in the left end face of the pushing head.

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