CN219936850U - Inductance trimming pin winding machine - Google Patents

Abstract

The utility model discloses an inductance wire-cutting and pin-winding machine, which comprises a main frame, a wire-cutting assembly and a pin-winding assembly, wherein the wire-cutting assembly and the pin-winding assembly are arranged on the main frame; the wire cutting assembly comprises a deck plate, a wire cutting clamping cylinder and a placing pressing plate, wherein the placing pressing plate is positioned in the middle of the deck plate, and a cutter block is connected to the driving end of the wire cutting clamping cylinder; the foot winding assembly comprises a foot winding rotary table, a foot winding motor, a lifting cylinder and a corner motor, wherein the driving end of the foot winding motor is in transmission connection with the middle part of the foot winding rotary table, a plurality of foot winding stations and auxiliary stations are arranged on the foot winding rotary table, a foot winding rotary shaft is arranged in the foot winding stations, the driving end of the lifting cylinder is connected with the corner motor, and the driving end of the corner motor is connected with the lower end of the driving rotary shaft in a clamping mode. The inductance trimming and pin winding machine integrates the trimming and pin winding procedures required by the inductance in the production process, reduces the occupied space of equipment, improves the automation procedure, has strong linkage capability between components, and keeps high-efficiency operation continuously.

Description

Inductance trimming pin winding machine

Technical Field

The utility model relates to the technical field of inductance production, in particular to an inductance wire-cutting and pin-winding machine.

Background

When the inductance product is produced, after the stitch thread ends extend out of the coil, the stitch thread ends need to be wound on the needle posts, the stitch thread ends are manually grasped by people to be wound, and then the stitch thread ends are cut by scissors after the winding is finished; the automatic trimming and foot winding of partial equipment can be achieved, but still manual work is needed to put the inductor and the base together, the foot can be automatically wound, the rest wire of the foot is finally trimmed off, the trimming and the foot winding are in the same linear conveying, the whole equipment is longer in length and large in occupied space, the inductor is needed to be put on the base in advance, and one process is added.

Disclosure of Invention

One object of the present utility model is to: the utility model provides an inductance is cut line and is wound foot machine, is put inductance and base together automatically, carries out the winding foot after cutting the line again, has improved production efficiency.

To achieve the purpose, the utility model adopts the following technical scheme:

an inductance wire-cutting and pin-winding machine comprises a main frame, a wire-cutting assembly and a pin-winding assembly, wherein the wire-cutting assembly and the pin-winding assembly are arranged on the main frame;

the wire cutting assembly comprises a table panel, a wire cutting clamping cylinder and a placing pressing plate, wherein the placing pressing plate is positioned in the middle of the table panel, the wire cutting clamping cylinder is positioned at two sides of the table panel, a cutter block is connected to the driving end of the wire cutting clamping cylinder, a clamping rod is fixed in the middle of the cutter block, a clamping spring is sleeved on the clamping rod, one end of the clamping spring is connected with the cutter block, and the other end of the clamping spring is connected with the clamping block;

the foot winding assembly comprises a foot winding turntable, a foot winding motor, a lifting cylinder and a corner motor, wherein the driving end of the foot winding motor is in transmission connection with the middle part of the foot winding turntable, a plurality of foot winding stations and auxiliary stations are arranged on the foot winding turntable, foot winding rotating shafts are arranged in the foot winding stations, the foot winding rotating shafts are in transmission connection through meshing gears, driving rotating shafts are arranged on the auxiliary stations, foot winding synchronous wheels are arranged on the driving rotating shafts, foot winding belt transmission connection is arranged between the foot winding synchronous wheels, the driving end of the lifting cylinder is connected with the corner motor, and the driving end of the corner motor is in clamping connection with the lower end of the driving rotating shaft.

As a preferable technical scheme, the optical fiber seat is arranged on the table top plate, and the sensing position of the optical fiber seat passes through the middle part of the placing pressing plate.

As a preferable technical scheme, the lower end of the auxiliary station is provided with a pin shaft, the lower end of the pin shaft is connected with a pin lower plate, a pin spring is sleeved on the pin shaft, the upper end of the pin shaft is connected with a pin block, the driving rotating shaft is sleeved with a pin wheel, and the pin block is inserted on the pin wheel.

As a preferred technical scheme, install the inductance subassembly on the master rack, go up the inductance subassembly and include first inductance carrier plate, second and go up inductance carrier plate, first inductance slide rail, second inductance slide rail, first propulsion cylinder, second propulsion cylinder and inductance lift-up plate, first inductance slide rail with the second inductance slide rail is all fixed in the master rack, the drive end of first propulsion cylinder with inductance lift-up plate is connected, be provided with first inductance slider on the inductance lift-up plate, first inductance slider slides on the first inductance slide rail, install the inductance lift-up cylinder on the inductance lift-up plate, the drive end of inductance lift-up cylinder with the bottom of first inductance carrier plate is connected, the both sides of second inductance carrier plate are provided with the second inductance slider, the second inductance slider slides on the second inductance slide rail, the drive end of second propulsion cylinder with the second is gone up the inductance carrier plate and is connected, first inductance carrier plate with the second inductance carrier plate is all provided with the upper jig.

As a preferable technical scheme, install base subassembly on the master unit frame, it includes the base vibration dish to go up the base subassembly, be connected with linear vibrator on the output of base vibration dish, linear vibrator's end is provided with horizontal mainboard, be provided with the carrier plate cylinder on the horizontal mainboard, be connected with the base carrier plate on the driven pole of carrier plate cylinder.

As an optimized technical scheme, the transverse main board is provided with a carrier plate sliding rail, the base carrier plate is provided with a carrier plate sliding block, and the carrier plate sliding block slides on the carrier plate sliding rail.

As a preferred technical scheme, the main frame is provided with a material moving assembly, the material moving assembly comprises a material moving support, a forward material moving seat and a backward material moving seat, the material moving support is provided with a material moving sliding rail, the forward material moving seat and the backward material moving seat are respectively provided with a material moving sliding block, the material moving sliding blocks slide on the material moving sliding rail, the forward material moving seat is provided with a material moving downward cylinder, the driving end of the material moving downward cylinder is connected with a front clamping cylinder, the backward material moving seat is fixedly provided with a material moving downward motor, the driving end of the material moving downward motor is connected with a material moving screw rod, the material moving screw rod is connected with a material moving nut sleeve in a threaded transmission manner, the material moving nut sleeve is fixedly provided with a material moving plate, the material moving plate moves along the vertical direction on the backward material moving seat, the lower end of the material moving plate is fixedly provided with a backward clamping cylinder, and the middle part of the front clamping cylinder and the middle part of the backward clamping cylinder are fixedly provided with a compression bar.

As an optimized technical scheme, a vertical wire arranging cylinder is further fixed below the material moving plate, a horizontal wire arranging cylinder is connected to the driving end of the vertical wire arranging cylinder, and a wire arranging pull plate is connected to the driving end of the horizontal wire arranging cylinder.

As a preferred technical scheme, install the blowing subassembly on the master cylinder frame, the blowing subassembly is including the blowing support and install preceding blowing motor on the blowing support, back blowing cylinder front blowing motor and back blowing cylinder, the drive end of preceding blowing motor is connected with preceding blowing frame through the transmission between preceding blowing wheel and the preceding blowing belt, be fixed with preceding vertical cylinder on the preceding blowing frame, install preceding blowing pneumatic clamping jaw on the drive end of preceding vertical cylinder, the drive end of back blowing cylinder is connected with back blowing frame, be fixed with back vertical cylinder on the back blowing frame, install back rotation cylinder on the drive end of back vertical cylinder, the drive end of back rotation cylinder is connected with back blowing pneumatic clamping jaw through the transmission between back blowing wheel and the back blowing belt.

As a preferable technical scheme, the main frame is provided with a discharging assembly, the discharging assembly comprises a discharging track, and discharging gratings are arranged on two sides of the discharging track.

The beneficial effects of the utility model are as follows: the inductance trimming and winding machine integrates trimming and winding procedures required by an inductor in the production process, reduces the occupied space of equipment, improves the automation procedure, has strong linkage capability between components and keeps high-efficiency operation continuously.

Drawings

The utility model is described in further detail below with reference to the drawings and examples.

Fig. 1 is a schematic diagram of an overall structure of an inductance wire-cutting and winding machine according to an embodiment;

fig. 2 is a schematic diagram of the overall structure of the upper inductor assembly according to the embodiment;

FIG. 3 is a schematic view of a material moving assembly according to an embodiment;

FIG. 4 is a schematic view of a forward moving base according to an embodiment;

FIG. 5 is a schematic view of a structure of a back-moving base according to an embodiment;

FIG. 6 is a schematic view of the overall structure of a wire cutting assembly according to an embodiment;

FIG. 7 is a partial block diagram of a wire cutting assembly according to an embodiment;

FIG. 8 is a schematic view of the overall structure of the upper base assembly according to the embodiment;

FIG. 9 is a schematic view of a first overall construction of a foot winding assembly according to an embodiment;

FIG. 10 is a schematic view of a second overall construction of a foot winding assembly according to an embodiment;

FIG. 11 is a schematic view of an auxiliary station according to an embodiment;

FIG. 12 is a schematic view of a foot winding station according to an embodiment;

FIG. 13 is a schematic view of the overall structure of the discharging assembly according to the embodiment;

FIG. 14 is a schematic view of the overall structure of the outfeed assembly according to the embodiment;

in fig. 1 to 14:

1. an upper inductor assembly; 101. a first upper inductor carrier plate; 102. the second upper inductor carrier plate; 103. a first inductor slide rail; 104. the second inductance sliding rail; 105. a first propulsion cylinder; 106. a second propulsion cylinder; 107. an inductance lifting plate; 108. an inductance jacking cylinder; 109. an upper inductance jig;

2. a material moving assembly; 201. a material transferring bracket; 202. advancing the material seat; 203. a material moving seat is moved backwards; 204. a material moving slide rail; 205. a material transferring and downward moving cylinder; 206. a front clamping cylinder; 207. a material moving and downward moving motor; 208. a material moving screw rod; 209. a material moving nut sleeve; 210. a material moving plate; 211. a rear clamping cylinder; 212. a compression bar; 213. a vertical wire arranging cylinder; 214. a horizontal wire arranging cylinder; 215. wire arranging pull plates;

3. a wire cutting assembly; 301. a deck plate; 302. the shearing line clamps the air cylinder; 303. placing a pressing plate; 304. a cutter block; 305. a clamping rod; 306. a clamping spring; 307. a clamping block; 308. an optical fiber seat;

4. an upper base assembly; 401. a base vibration plate; 402. a carrier plate cylinder; 403. a linear vibrator; 404. a transverse main board; 405. a base carrier plate; 406. a carrier plate slide rail;

5. a foot winding assembly; 501. a foot winding turntable; 502. a foot winding motor; 503. a lifting cylinder; 504. a corner motor; 505. a foot winding station; 506. an auxiliary station; 507. a foot winding rotating shaft; 508. a driving rotating shaft; 509. a foot winding synchronous wheel; 510. pin shaft insertion; 511. a lower plate of the bolt; 512. a latch spring; 513. a latch block; 514. a latch wheel;

6. a discharging assembly; 601. a discharging bracket; 602. a front discharging motor; 603. a rear discharging cylinder; 604. a front discharging wheel; 605. a front discharging belt; 606. a front discharging frame; 607. a front vertical cylinder; 608. front discharging pneumatic clamping jaw; 609. a rear discharging frame; 610. a rear vertical cylinder; 611. a rear rotary cylinder; 612. a rear discharging wheel; 613. rear discharging pneumatic clamping jaws;

7. a discharge assembly; 701. a discharge rail; 702. a discharge grating;

8. and a main frame.

Detailed Description

The technical scheme of the utility model is further described below by the specific embodiments with reference to the accompanying drawings.

As shown in fig. 1, in this embodiment, an inductance wire-cutting and winding machine includes a main frame 8, an upper inductance component 1 mounted on the main frame 8, a material moving component 2, a wire-cutting component 3, an upper base component 4, a wire-winding component 5, a material discharging component 6 and a material discharging component 7, wherein the upper inductance component 1 is responsible for placing and waiting for moving an entire row of inductance, the material moving component 2 moves the inductance from the upper inductance component 1 to the wire-cutting component 3 for wire-cutting, then moves the inductance from the wire-cutting component 3 to the wire-winding component 5 for combining with the base, the upper base component 4 synchronously carries the base, the material discharging component 6 moves the base from the upper base component 4 into the wire-winding component 5, and grabs the inductance component completed by the wire-winding to the material discharging component 7 for removing.

As shown in fig. 2, the upper inductor assembly 1 includes a first upper inductor carrier plate 101, a second upper inductor carrier plate 102, a first inductor slide rail 103, a second inductor slide rail 104, a first pushing cylinder 105, a second pushing cylinder 106 and an inductor lifting plate 107, wherein the first inductor slide rail 103 and the second inductor slide rail 104 are both fixed on the main frame 8, the driving end of the first pushing cylinder 105 is connected with the inductor lifting plate 107, a first inductor slide block is arranged on the inductor lifting plate 107, the first inductor slide block slides on the first inductor slide rail 103, an inductor lifting cylinder 108 is arranged on the inductor lifting plate 107, the driving end of the inductor lifting cylinder 108 is connected with the bottom of the first upper inductor carrier plate 101, two sides of the second upper inductor carrier plate 102 are provided with second inductor slide blocks, the second inductor slide blocks slide on the second inductor slide rail 104, the driving end of the second pushing cylinder 106 is connected with the second upper inductor carrier plate 102, and upper inductor jigs 109 are arranged on the first upper inductor carrier plate 101 and the second upper inductor carrier plate 102.

The whole row of inductors are placed on the first upper inductor jig 109 manually or by a mechanical arm, the driving end of the inductor jacking cylinder 108 is contracted, the first upper inductor carrier plate 101 is controlled to drive the first upper inductor jig 109 to move downwards by a certain height, under the condition that the second upper inductor carrier plate 102 is not influenced, the first pushing cylinder 105 controls the first upper inductor carrier plate 101 to slide into the main frame 8 along the first inductor sliding rail 103, the inductor jacking cylinder 108 jacks the first upper inductor carrier plate 101, the second pushing cylinder 106 pushes the second upper inductor carrier plate 102 out of the empty second upper inductor jig 109 in the process, after the second upper inductor carrier plate 101 is empty, the inductor jacking cylinder 108 is perforated to the first upper inductor carrier plate 101 to move downwards to push out the inductor, the second upper inductor carrier plate 102 moves in, and the circulating operation is performed, so that the continuous working procedure is ensured.

As shown in fig. 3 to 5, the material transferring assembly 2 includes a material transferring support 201, a front material transferring seat 202 and a rear material transferring seat 203, a material transferring slide rail 204 is disposed on the material transferring support 201, material transferring slide blocks are disposed on the front material transferring seat 202 and the rear material transferring seat 203, the material transferring slide blocks slide on the material transferring slide rail 204, a material transferring and down-transferring cylinder 205 is disposed on the front material transferring seat 202, a front clamping cylinder 206 is connected to a driving end of the material transferring and down-transferring cylinder 205, a material transferring and down-transferring motor 207 is fixed on the rear material transferring seat 203, a material transferring screw rod 208 is connected to a driving end of the material transferring and down-transferring motor 207, a material transferring nut sleeve 209 is connected to the material transferring screw rod 208 in a threaded transmission manner, a material transferring plate 210 is fixed on the material transferring nut sleeve 209, the material transferring plate 210 moves on the rear material transferring seat 203 along the vertical direction, a rear clamping cylinder 211 is fixed at a lower end of the material transferring plate 210, and a pressing rod 212 is fixed at a middle part of the front clamping cylinder 206 and a middle part of the rear clamping cylinder 211.

The material moving and downward moving cylinder 205 on the material moving seat 202 controls the front clamping cylinder 206 to drop onto the upper inductor assembly 1 to clamp the inductor, and the inductor is lifted and then moved onto the wire cutting assembly 3 to be placed.

As shown in fig. 6 and 7, the wire cutting assembly 3 includes a deck plate 301, a wire cutting clamping cylinder 302 and a placing pressing plate 303, the placing pressing plate 303 is located in the middle of the deck plate 301, the wire cutting clamping cylinder 302 is located at two sides of the deck plate 301, a cutter block 304 is connected to the driving end of the wire cutting clamping cylinder 302, a clamping rod 305 is fixed in the middle of the cutter block 304, a clamping spring 306 is sleeved on the clamping rod 305, one end of the clamping spring 306 is connected with the cutter block 304, the other end of the clamping spring 306 is connected with a clamping block 307, an optical fiber seat 308 is mounted on the deck plate 301, and the sensing position of the optical fiber seat 308 passes through the middle of the placing pressing plate 303.

After the optical fiber seat 308 senses the inductance, the shearing clamping cylinder 302 controls the copper wire position of the cutter block 304 close to the inductance, the clamping block 307 clamps the copper wire under the action of the clamping spring 306, after the copper wire is cut off by the cutter block 304, the shearing clamping cylinder 302 retreats, the clamping block 307 is loosened, and the cutter block 304 leaves the inductance.

A vertical wire arranging cylinder 213 is also fixed below the material moving plate 210, a horizontal wire arranging cylinder 214 is connected to the driving end of the vertical wire arranging cylinder 213, and a wire arranging pull plate 215 is connected to the driving end of the horizontal wire arranging cylinder 214.

Then, the material moving and downward moving motor 207 on the material moving seat 203 moves the material moving plate 210 downward through the material moving screw rod 208, the rear clamping cylinder 211 clamps the cut-out inductance, the vertical wire arranging cylinder 213 controls the horizontal wire arranging cylinder 214 to move downward, the horizontal wire arranging cylinder 214 controls the wire arranging pull plates 215 on two sides to draw close to the middle, the copper wires are straightened, and then the inductance is placed in the foot winding assembly 5.

As shown in fig. 8, while the inductance processing is performed, the upper base assembly 4 includes a base vibration plate 401, a linear vibrator 403 is connected to an output end of the base vibration plate 401, a transverse main plate 404 is disposed at an end of the linear vibrator 403, a carrier plate cylinder 402 is disposed on the transverse main plate 404, and a base carrier plate 405 is connected to a driving rod of the carrier plate cylinder 402.

Moreover, a carrier slide rail 406 is provided on the transverse main board 404, a carrier slide block is provided on the base carrier 405, and the carrier slide block slides on the carrier slide rail 406.

The base is vibrated out of the base vibrating plate 401, conveyed by the linear vibrator 403 to the base carrier plates 405 on the transverse main plate 404, and after the bases are mounted on the base carrier plates 405 on both sides, the material is taken by the material discharging component 6 and moved to the leg winding component 5.

As shown in fig. 9 to 12, the foot winding assembly 5 includes a foot winding turntable 501, a foot winding motor 502, a lifting cylinder 503 and a corner motor 504, wherein a driving end of the foot winding motor 502 is in transmission connection with the middle part of the foot winding turntable 501, a plurality of foot winding stations 505 and auxiliary stations 506 are arranged on the foot winding turntable 501, foot winding rotating shafts 507 are arranged in the foot winding stations 505, the foot winding rotating shafts 507 are in transmission connection through meshed gears, driving rotating shafts 508 are arranged on the auxiliary stations 506, foot winding synchronous wheels 509 are arranged on the driving rotating shafts 508 and the foot winding rotating shafts 507, the foot winding synchronous wheels 509 are in transmission connection through foot winding belts, a driving end of the lifting cylinder 503 is connected with the corner motor 504, and a driving end of the corner motor 504 is in clamping connection with the lower end of the driving rotating shafts 508.

Moreover, a pin shaft 510 is provided at the lower end of the auxiliary station 506, a pin lower plate 511 is connected to the lower end of the pin shaft 510, a pin spring 512 is sleeved on the pin shaft 510, a pin block 513 is connected to the upper end of the pin shaft 510, a pin wheel 514 is sleeved on the driving shaft 508, and the pin block 513 is inserted on the pin wheel 514.

The lifting cylinder 503 controls the corner motor 504 to lift, the driving end of the corner motor 504 lifts, when the lower bolt plate 511 is jacked, the bolt spring 512 contracts, the bolt block 513 leaves the bolt wheel 514, the bolt wheel 514 can rotate along with the driving rotating shaft 508, the corner motor 504 controls the driving rotating shaft 508 to rotate, the copper wire of the inductor is wound on the base around the upper end of the foot rotating shaft 507 under the transmission of the foot synchronous wheel 509, after the corner motor 504 is controlled to descend by the lifting cylinder 503, the bolt spring 512 stretches, the bolt block 513 is reinserted into the bolt wheel 514, the driving rotating shaft 508 can not rotate any more, and the positions of the inductor and the base are fixed.

As shown in fig. 13, the discharging assembly 6 includes a discharging support 601, a front discharging motor 602 installed on the discharging support 601, a rear discharging cylinder 603, a front discharging motor 602 and a rear discharging cylinder 603, a front discharging frame 606 is connected to a driving end of the front discharging motor 602 through transmission between the front discharging wheel 604 and a front discharging belt 605, a front vertical cylinder 607 is fixed to the front discharging frame 606, a front discharging pneumatic clamping jaw 608 is installed to a driving end of the front vertical cylinder 607, a rear discharging frame 609 is connected to a driving end of the rear discharging cylinder 603, a rear vertical cylinder 610 is fixed to the rear discharging frame 609, a rear rotating cylinder 611 is installed to a driving end of the rear vertical cylinder 610, and a rear discharging pneumatic clamping jaw 613 is connected to a driving end of the rear rotating cylinder 611 through transmission between the rear discharging wheel 612 and the rear discharging belt.

After the foot winding assembly 5 finishes winding the inductor and the base, the rear discharging air cylinder 603 controls the rear discharging pneumatic clamping jaw 613 to grasp the inductor product, and the inductor product is placed on the discharging assembly 7 by the rotating angle under the action of the rear rotating air cylinder 611.

As shown in fig. 14, the discharging assembly 7 includes a discharging track 701, two sides of the discharging track 701 are provided with discharging gratings 702, and when the discharging gratings 702 sense the inductive product, the discharging track 701 transmits a signal to a soldering device at the rear end for soldering.

It should be noted that the above embodiments are merely preferred embodiments of the present utility model and the applied technical principles, and any changes or substitutions easily conceivable to those skilled in the art within the scope of the present utility model are included in the scope of the present utility model.

Claims (10)

1. The inductance wire-cutting and pin-winding machine is characterized by comprising a main frame, a wire-cutting assembly and a pin-winding assembly, wherein the wire-cutting assembly and the pin-winding assembly are arranged on the main frame;

the wire cutting assembly comprises a table panel, a wire cutting clamping cylinder and a placing pressing plate, wherein the placing pressing plate is positioned in the middle of the table panel, the wire cutting clamping cylinder is positioned at two sides of the table panel, a cutter block is connected to the driving end of the wire cutting clamping cylinder, a clamping rod is fixed in the middle of the cutter block, a clamping spring is sleeved on the clamping rod, one end of the clamping spring is connected with the cutter block, and the other end of the clamping spring is connected with the clamping block;

the foot winding assembly comprises a foot winding turntable, a foot winding motor, a lifting cylinder and a corner motor, wherein the driving end of the foot winding motor is in transmission connection with the middle part of the foot winding turntable, a plurality of foot winding stations and auxiliary stations are arranged on the foot winding turntable, foot winding rotating shafts are arranged in the foot winding stations, the foot winding rotating shafts are in transmission connection through meshing gears, driving rotating shafts are arranged on the auxiliary stations, foot winding synchronous wheels are arranged on the driving rotating shafts, foot winding belt transmission connection is arranged between the foot winding synchronous wheels, the driving end of the lifting cylinder is connected with the corner motor, and the driving end of the corner motor is in clamping connection with the lower end of the driving rotating shaft.

2. The inductive trimming and pin winding machine of claim 1, wherein the deck plate is provided with an optical fiber seat, and the sensing position of the optical fiber seat passes through the middle of the placing pressing plate.

3. The inductive wire-cutting and pin-winding machine according to claim 1, wherein a pin shaft is arranged at the lower end of the auxiliary station, a pin lower plate is connected to the lower end of the pin shaft, a pin spring is sleeved on the pin shaft, a pin block is connected to the upper end of the pin shaft, a pin wheel is sleeved on the driving rotating shaft, and the pin block is inserted on the pin wheel.

4. The inductive trimming and pin winding machine according to claim 1, wherein an upper inductive component is mounted on the main frame and comprises a first upper inductive carrier plate, a second upper inductive carrier plate, a first inductive sliding rail, a second inductive sliding rail, a first pushing cylinder, a second pushing cylinder and an inductive jacking plate, the first inductive sliding rail and the second inductive sliding rail are fixed on the main frame, the driving end of the first pushing cylinder is connected with the inductive jacking plate, a first inductive sliding block is arranged on the inductive jacking plate, the first inductive sliding block slides on the first inductive sliding rail, an inductive jacking cylinder is mounted on the inductive jacking plate, the driving end of the inductive jacking cylinder is connected with the bottom of the first upper inductive carrier plate, the two sides of the second upper inductive carrier plate are provided with second inductive sliding blocks, the driving end of the second pushing cylinder is connected with the second inductive carrier plate, and the first inductive carrier plate is connected with the second inductive carrier plate.

5. The inductive wire-cutting and pin-winding machine according to claim 1, wherein an upper base assembly is mounted on the main frame and comprises a base vibration disc, a linear vibrator is connected to the output end of the base vibration disc, a transverse main plate is arranged at the tail end of the linear vibrator, a carrier plate cylinder is arranged on the transverse main plate, and a base carrier plate is connected to a driving rod of the carrier plate cylinder.

6. The inductance wire-cutting and pin-winding machine according to claim 5, wherein a carrier slide rail is arranged on the transverse main board, a carrier slide block is arranged on the base carrier plate, and the carrier slide block slides on the carrier slide rail.

7. The inductive trimming and pin winding machine according to claim 1, wherein the main frame is provided with a material moving assembly, the material moving assembly comprises a material moving support, a front material moving seat and a rear material moving seat, the material moving support is provided with a material moving sliding rail, the front material moving seat and the rear material moving seat are respectively provided with a material moving sliding block, the material moving sliding blocks slide on the material moving sliding rail, the front material moving seat is provided with a material moving and descending cylinder, the driving end of the material moving and descending cylinder is connected with a front clamping cylinder, the rear material moving seat is fixedly provided with a material moving and descending motor, the driving end of the material moving and descending motor is connected with a material moving screw rod, the material moving screw rod is in threaded transmission connection with a material moving nut sleeve, the material moving nut sleeve is fixedly provided with a material moving plate, the material moving plate moves on the rear material moving seat along the vertical direction, the lower end of the material moving plate is fixedly provided with a rear clamping cylinder, and the middle part of the front clamping cylinder and the middle part of the rear clamping cylinder are fixedly provided with a compression bar.

8. The inductive trimming and pin winding machine according to claim 7, wherein a vertical wire arranging cylinder is further fixed below the material moving plate, a horizontal wire arranging cylinder is connected to a driving end of the vertical wire arranging cylinder, and a wire arranging pull plate is connected to a driving end of the horizontal wire arranging cylinder.

9. The inductive trimming pin winding machine according to claim 1, wherein the main frame is provided with a discharging assembly, the discharging assembly comprises a discharging support, a front discharging motor, a rear discharging cylinder, a front discharging motor and a rear discharging cylinder, the front discharging motor is arranged on the discharging support, the driving end of the front discharging motor is connected with a front discharging frame through transmission between a front discharging wheel and a front discharging belt, a front vertical cylinder is fixed on the front discharging frame, a front discharging pneumatic clamping jaw is arranged on the driving end of the front vertical cylinder, the driving end of the rear discharging cylinder is connected with a rear discharging frame, a rear vertical cylinder is fixed on the rear discharging frame, a rear rotating cylinder is arranged on the driving end of the rear vertical cylinder, and the driving end of the rear rotating cylinder is connected with a rear discharging pneumatic clamping jaw through transmission between the rear discharging wheel and the rear discharging belt.

10. The inductive trimming and pin winding machine according to claim 1, wherein the main frame is provided with a discharging assembly, the discharging assembly comprises a discharging track, and discharging gratings are arranged on two sides of the discharging track.