CN219716812U - Electronic component sleeve device - Google Patents

Abstract

The utility model relates to the technical field of nonstandard automation, in particular to an electronic element sleeve device, which comprises a discharging assembly, a correction guide assembly, a guide driving assembly, a sleeve blanking assembly and a sleeve positioning assembly, wherein the correction guide assembly is used for correcting and guiding transmission of a sleeve discharged by the discharging assembly; the guiding driving assembly comprises a driving roller, a driven roller and a driving module for driving the driving roller, and a gap for passing through the sleeve is formed between the driving roller and the driven roller; the sleeve cutting assembly comprises a guide pipe connected to the lower side of the gap and a cutting module positioned on the lower side of the guide pipe; the sleeve positioning assembly comprises a lifting module and a clamping module connected to the lifting module. The utility model solves the problem of low efficiency of the existing manual sleeve, completes the whole automation, has high working efficiency and ensured precision, and is suitable for the automatic production of the diode products of the electronic elements.

Description

Electronic component sleeve device

Technical Field

The utility model relates to the technical field of nonstandard automation, in particular to an electronic element sleeve device.

Background

Automation technology is widely used in industry, agriculture, military, scientific research, transportation, commerce, medical, services, and households. By adopting the automation technology, people can be liberated from heavy physical labor, partial mental labor and severe and dangerous working environments, the organ functions of the people can be expanded, the labor productivity is greatly improved, and the ability of the people to know and reform the world is enhanced. Large-scale complete equipment, also known as automation equipment, in an automation system. Refers to a process in which a machine or device automatically operates or controls in accordance with a prescribed program or instruction without human intervention.

In the production process of the electronic element diode, a sleeve is required to be sleeved outside, pins are bent and formed to a specified shape, the existing process is mostly completed through manual operation, pin bending is completed through a jig, the manual operation efficiency in the sleeve process is low, the precision is difficult to master, the production efficiency is low, and the labor cost is high.

Disclosure of Invention

In order to solve the problems, the utility model provides the electronic element sleeve device which solves the problem of low efficiency of the existing manual sleeve, is integrally and automatically finished, has high working efficiency and ensured precision, and is suitable for automatic production of electronic element diode products.

The technical scheme adopted by the utility model is as follows: the sleeve device for the electronic component comprises a discharging assembly, a correction guide assembly, a guide driving assembly, a sleeve cutting assembly and a sleeve positioning assembly, wherein the discharging assembly is used for discharging the sleeve; the correction guide assembly is used for correcting and guiding the sleeve discharged by the discharging assembly; the guiding driving assembly comprises a driving roller, a driven roller and a driving module for driving the driving roller, wherein the driving module is used for driving the driving roller to rotate, and a gap for a sleeve to pass through is formed between the driving roller and the driven roller; the sleeve cutting assembly comprises a guide pipe connected to the lower side of the gap and a cutting module positioned on the lower side of the guide pipe, the guide pipe is used for receiving the sleeve led in by the guide driving assembly, and the cutting module is used for cutting the sleeve; the sleeve positioning assembly comprises a lifting module and a clamping module connected with the lifting module, wherein the clamping module is used for clamping the cut sleeve and sleeving the cut sleeve on the electronic element under the action of the lifting module.

The electronic component clamping device is characterized by further comprising a turntable assembly, wherein a plurality of clamping jaws are circumferentially arranged on the turntable assembly and used for clamping the electronic component, the turntable assembly drives the clamping jaws to rotate, and the clamping module is used for clamping the cut sleeve and sleeving the cut sleeve onto the electronic component clamped by the clamping jaws under the action of the lifting module.

The further improvement to above-mentioned scheme does, the blowing subassembly includes the support frame, installs the blowing support on the support frame top and installs the blowing dish on the blowing support, the tension roller is installed to the blowing support, the blowing dish is used for the sleeve pipe blowing.

The further improvement to above-mentioned scheme is, the support frame includes L type support and connects in the installation panel of L type support, correct guiding component, direction drive assembly, sleeve pipe blank subassembly and sleeve pipe locating component all install on the installation panel.

In a further improvement of the above scheme, the correction guide assembly comprises a correction seat and a guide seat, wherein the correction seat is arranged above the guide seat and used for being conveyed to the guide seat after being corrected by the sleeve.

The further improvement of the scheme is that the correction seat is provided with a correction groove, the wall surface of the correction groove is symmetrically provided with a V-shaped groove, and one side of the V-shaped groove is provided with a feeding sensor.

The improvement of the scheme is that the guide seat is provided with a slot, the slot is provided with a guide block, the guide block is provided with a guide groove, the guide groove is provided with an expansion port towards the correction groove, and the correction groove is a flat pull groove.

The technical scheme is further improved in that a driving gear is arranged on one side of the driving roller, a driven gear is arranged on one side of the driven roller, the driving gear is used for meshing with the driven gear, the driving module is used for driving the driving gear and the driving roller to synchronously drive, and the driven roller follows the driving roller to rotate and drive when the driven gear is meshed with the driving gear.

According to the scheme, the driven roller is connected with the sliding block, the sliding block is connected with the moving cylinder, and the moving cylinder is used for driving the sliding block to drive the driven roller to move towards the position of the driving roller and enabling the driven gear to be meshed with the driving gear.

The guide pipe comprises a feeding head and a discharging head, wherein concave cambered surfaces are symmetrically arranged on two sides of the feeding head, the concave cambered surfaces correspond to the driving roller and the driven roller respectively, and the discharging head is used for connecting the cutting-off module.

The cutting module comprises a cutter support, a cutter cylinder arranged at one end of the cutter support, a movable block connected with the cutter cylinder and movable in the cutter support, and a sleeve cutter connected with the movable block, wherein a cutter edge of the sleeve cutter is abutted against the lower surface of the cutter support, and the discharge head is fixed at one end of the cutter support and corresponds to the cutter edge of the sleeve cutter at the discharge port.

The lifting module is a sliding table cylinder, the driving end of the lifting module is connected with an L-shaped block, the clamping module is arranged on the lower surface of the L-shaped block, the upper surface of the L-shaped block is provided with a pressing module, and the pressing module is used for pressing the sleeve into the electronic element.

In a further improvement of the above scheme, the pressing module comprises a pressing cylinder and a pressing block connected with the pressing cylinder, wherein the pressing block is used for pressing the sleeve into the electronic component.

The clamping module comprises a clamping cylinder and clamping claws connected with the clamping cylinder, wherein the clamping claws are used for clamping the sleeve.

The clamping claw comprises clamping plates which are symmetrical to each other, positioning holes and positioning pins are formed in the clamping plates after being combined, the positioning holes are used for positioning pins of electronic elements, the positioning pins are used for positioning sleeves, and one ends of the positioning holes penetrate through the positioning pins.

The beneficial effects of the utility model are as follows:

compared with the existing electronic element sleeve, the full-automatic sleeve is adopted, the discharging assembly is used for discharging the sleeve, the sleeve is guided by correction after discharging, the sleeve is guided to the sleeve cutting assembly by guide driving to cut, the sleeve is positioned and clamped by the sleeve positioning assembly to a specified length under the action of the lifting assembly before cutting, and then the sleeve is cut off, and in the cutting process, the clamping module sleeves the sleeve on the electronic element while stretching of the lifting module, so that the sleeve action is synchronously completed, the time is saved, and the working efficiency is high; the problem of current inefficiency through artifical sleeve pipe is solved, whole automation is accomplished, and work efficiency is high, and the precision is guaranteed, is applicable to the automated production of electronic component diode product. The device comprises a discharging assembly, a correction guiding assembly, a guiding driving assembly, a sleeve cutting assembly and a sleeve positioning assembly, wherein the discharging assembly is used for discharging the sleeve; the correction guide assembly is used for correcting and guiding the sleeve discharged by the discharging assembly; the guiding driving assembly comprises a driving roller, a driven roller and a driving module for driving the driving roller, wherein the driving module is used for driving the driving roller to rotate, and a gap for a sleeve to pass through is formed between the driving roller and the driven roller; the sleeve cutting assembly comprises a guide pipe connected to the lower side of the gap and a cutting module positioned on the lower side of the guide pipe, the guide pipe is used for receiving the sleeve led in by the guide driving assembly, and the cutting module is used for cutting the sleeve; the sleeve positioning assembly comprises a lifting module and a clamping module connected with the lifting module, wherein the clamping module is used for clamping the cut sleeve and sleeving the cut sleeve on the electronic element under the action of the lifting module. The sleeve can be automatically sleeved on the electronic element after being corrected and guided, so that the automatic sleeve of the electronic element is realized, the automatic sleeve is realized, the labor is saved, the automation degree is high, and the working efficiency is high.

Drawings

FIG. 1 is a schematic perspective view of an electronic component bushing apparatus according to the present utility model;

FIG. 2 is a perspective view of the electronic component bushing apparatus of FIG. 1 from another perspective;

FIG. 3 is a perspective view of the electronic component bushing apparatus of FIG. 1 from another perspective;

FIG. 4 is a partial perspective view of the electronic component bushing apparatus of FIG. 1;

FIG. 5 is a schematic view of the electronic component bushing apparatus of FIG. 1;

fig. 6 is a perspective view of a sleeve blanking assembly of the electronic component sleeve apparatus of fig. 1;

FIG. 7 is a perspective view of a sleeve positioning assembly of the electronic component sleeve apparatus of FIG. 1;

FIG. 8 is a schematic perspective view of a clamping module of the electronic component sleeve device of FIG. 1;

fig. 9 is an exploded view of a clamping module of the electronic component bushing apparatus of fig. 1.

Reference numerals illustrate: the device comprises a discharging assembly 1, a supporting frame 11, an L-shaped bracket 111, a mounting panel 112, a discharging bracket 12, a tension roller 121 and a discharging disc 13;

correction guide assembly 2, correction seat 21, correction groove 211, V-shaped groove 212, feeding sensor 213, guide seat 22, slot 221, guide block 222, and guide groove 223;

the guide driving assembly 3, the driving roller 31, the driving gear 311, the driven roller 32, the driven gear 321, the sliding block 322, the moving cylinder 323 and the driving module 33;

the sleeve cutting assembly 4, the guide tube 41, the feeding head 411, the discharging head 412, the concave cambered surface 413, the cutting module 42, the cutter bracket 421, the cutter cylinder 422, the movable block 423 and the sleeve cutter 424;

the sleeve positioning assembly 5, the lifting module 51, the L-shaped block 511, the clamping module 52, the clamping cylinder 521, the clamping claw 522, the clamping plate 522a, the positioning hole 522b, the positioning pin 522c, the pressing die set 53, the pressing cylinder 531 and the pressing block 532;

turntable assembly 6, clamping jaw 61.

Detailed Description

In order that the utility model may be readily understood, a more complete description of the utility model will be rendered by reference to the appended drawings. Preferred embodiments of the present utility model are shown in the drawings. This utility model may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model.

As shown in fig. 1 to 9, in one embodiment of the present utility model, an electronic component bushing apparatus is provided with a blanking assembly 1, a correction guide assembly 2, a guide driving assembly 3, a bushing blanking assembly 4, and a bushing positioning assembly 5, wherein the blanking assembly 1 is used for bushing blanking; the correction guide assembly 2 is used for correcting and guiding the sleeve discharged by the discharging assembly 1; the guiding driving assembly 3 comprises a driving roller 31, a driven roller 32 and a driving module 33 for driving the driving roller 31, wherein the driving module 33 is used for driving the driving roller 31 to rotate, and a gap for passing a sleeve is arranged between the driving roller 31 and the driven roller 32; the sleeve cutting assembly 4 comprises a guide pipe 41 connected to the lower side of the gap and a cutting module 42 positioned on the lower side of the guide pipe 41, wherein the guide pipe 41 is used for receiving a sleeve led in by the guide driving assembly 3, and the cutting module 42 is used for cutting the sleeve; the sleeve positioning assembly 5 comprises a lifting module 51 and a clamping module 52 connected to the lifting module 51, wherein the clamping module 52 is used for clamping the cut sleeve and sleeving the cut sleeve on the electronic component under the action of the lifting module 51.

Referring to fig. 1-2, the preferred embodiment further includes a turntable assembly 6, a plurality of clamping jaws 61 are circumferentially disposed on the turntable assembly 6, the clamping jaws 61 are used for clamping electronic components, the turntable assembly 6 drives the clamping jaws 61 to rotate, the clamping module 52 is used for clamping a cut-off sleeve and sleeving the cut-off sleeve onto the electronic components clamped by the clamping jaws 61 under the action of the lifting module 51, the turntable assembly 6 and the clamping jaws 61 are matched for feeding the electronic components in a rotating manner, and the clamping jaws 61 clamp the electronic components and then automatically rotate the sleeve, so that the degree of automation is high.

As shown in fig. 3 to 4, it is further preferable that the discharging assembly 1 of the above embodiment includes a supporting frame 11, a discharging support 12 installed at the top end of the supporting frame 11, and a discharging tray 13 installed on the discharging support 12, where the discharging support 12 is installed with a tension roller 121, and the discharging tray 13 is used for discharging the sleeve; the supporting frame 11 and the discharging support 12 are matched to support the discharging tray 13, and the tension roller 121 is used for stretching sleeve discharging tension and discharging is stable.

It is further preferable to the above embodiment that the supporting frame 11 includes an L-shaped bracket 111 and a mounting panel 112 connected to the L-shaped bracket 111, and the correction guide assembly 2, the guide driving assembly 3, the sleeve blanking assembly 4 and the sleeve positioning assembly 5 are all mounted on the mounting panel 112, and the L-shaped bracket 111 is matched with the mounting panel 112 for structural mounting of each assembly, so that the overall structure is convenient to mount and has good structural stability.

It is further preferred that the correction guidance assembly 2 comprises a correction seat 21 and a lead-in seat 22, the correction seat 21 being located above the lead-in seat 22 and being adapted to be fed into the lead-in seat 22 after correction of the sleeve.

It is further preferable for the above embodiment that the correction seat 21 is provided with a correction groove 211, a V-shaped groove 212 is symmetrically provided on a groove wall surface of the correction groove 211, and a feeding sensor 213 is provided on one side of the V-shaped groove 212; the flat sleeve is flattened and corrected through the matching of the double symmetrical V-shaped grooves 212, and meanwhile, a feeding sensor 213 is arranged for sensing sleeve feeding.

It is further preferable that the above embodiment is that the insertion groove 221 is formed in the insertion groove 221, the insertion groove 221 is inserted with the insertion block 222, the insertion groove 223 is formed in the insertion block 222, the insertion groove 223 is formed toward the correction groove 211, the correction groove 211 is a flat pull groove, the directions of the insertion groove 223 and the V-shaped groove 212 are cross, the flat sleeve can be formed into a rectangular sleeve, and the sleeve can be ensured to be stably sleeved on the electronic component.

As shown in fig. 5, it is further preferable for the above embodiment that a driving gear 311 is disposed on one side of the driving roller 31, a driven gear 321 is disposed on one side of the driven roller 32, the driving gear 311 is used for engaging with the driven gear 321, the driving module 33 is used for driving the driving gear 311 and the driving roller 31 to synchronously drive, and the driven roller 32 follows the driving roller 31 to rotate when the driven gear 321 is engaged with the driving gear 311; the driving gear 311 and the driven gear 321 can form a double rolling guide roller under the cooperation, so that the sleeve can be led downwards to drive.

It is further preferable for the above embodiment that the driven roller 32 is connected with a sliding block 322, the sliding block 322 is connected with a moving cylinder 323, the moving cylinder 323 is used for driving the sliding block 322 to drive the driven roller 32 to move towards the position of the driving roller 31 and enable the driven gear 321 to be meshed with the driving gear 311, the moving cylinder 323 is arranged to drive the sliding block 322 to drive the driven gear 321 and the driven roller 32 to move, when the two gears are meshed, the two rollers are synchronously driven to drive the sleeve to be conveyed, and the feeding can be stopped after the moving cylinder 323 is driven to be separated.

It is further preferable to the above embodiment that the guide tube 41 includes a feeding head 411 and a discharging head 412, wherein concave cambered surfaces 413 are symmetrically provided on two sides of the feeding head 411, the concave cambered surfaces 413 respectively correspond to the driving roller 31 and the driven roller 32, the discharging head 412 is used for connecting the cutting-off module 42, two ends of the guide tube 41 are respectively used for feeding and discharging the sleeve, the concave cambered surfaces 413 are convenient for matching with the two rollers to convey the sleeve, and the discharging head 412 is connected with the cutting-off module 42 so as to cut the sleeve discharged to the specified size.

Referring to fig. 6, it is further preferable that the cutting module 42 of the above embodiment includes a cutter frame 421, a cutter cylinder 422 mounted at one end of the cutter frame 421, a movable block 423 connected to the cutter cylinder 422 and movable to the cutter frame 421, and a sleeve cutter 424 connected to the movable block 423, the edge of the sleeve cutter 424 abuts against the lower surface of the cutter frame 421, and the discharge head 412 is fixed at one end of the cutter frame 421, and the discharge port corresponds to the edge of the sleeve cutter 424, and the cutter cylinder 422 drives the movable block 423 to drive the sleeve cutter 424 to cut the sleeve.

Referring to fig. 7 to 9, in a further preferred embodiment of the foregoing embodiment, the lifting module 51 is a sliding table cylinder, the driving end of the lifting module is connected with an L-shaped block 511, the clamping module 52 is mounted on the lower surface of the L-shaped block 511, the upper surface of the L-shaped block 511 is mounted with a pressing module 53, and the pressing module 53 is used for pressing the sleeve into the electronic component; the sleeve can be press-fitted by the lifting module 51 through the pressing module 53.

It is further preferable for the above embodiment that the pressing die set 53 includes a pressing cylinder 531, and a pressing block 532 connected to the pressing cylinder 531, the pressing block 532 being for pressing the sleeve into the electronic component, the pressing block 532 being driven by the pressing cylinder 531 to press-fit the sleeve.

It is further preferable for the above embodiment that the clamping module 52 includes a clamping cylinder 521, a clamping claw 522 connected to the clamping cylinder 521, the clamping claw 522 for clamping the sleeve, and the clamping claw 522 is driven by the clamping cylinder 521 for clamping and fixing the sleeve.

Referring to fig. 9, it is further preferable that the holding claw 522 includes mutually symmetrical holding plates 522a, the symmetrical holding plates 522a are combined to form a positioning hole 522b and a positioning pin 522c, the positioning hole 522b is used for positioning pins of the electronic component, the positioning pin 522c is used for positioning a sleeve, one end of the positioning hole 522b penetrates through the positioning pin 522c, in the sleeve process, one end of the sleeve is fixed through the positioning hole 522b and the positioning pin 522c, pins can be positioned during sleeve, positioning precision is high during sleeve positioning, and sleeve precision is high.

The full-automatic sleeve is adopted, the discharging assembly 1 is used for discharging the sleeve, the sleeve is guided to the sleeve cutting assembly 4 through correction and guide after discharging, the sleeve is guided to be driven to be guided to be cut, the sleeve is positioned and clamped by the sleeve positioning assembly 5 to be stretched to a specified length under the action of the lifting assembly before cutting, and then the sleeve is cut off, in the cutting process, the clamping module 52 is used for sleeving the sleeve on an electronic element while stretching the lifting module 51, so that the sleeve action is synchronously completed, the time is saved, and the working efficiency is high; the problem of current inefficiency through artifical sleeve pipe is solved, whole automation is accomplished, and work efficiency is high, and the precision is guaranteed, is applicable to the automated production of electronic component diode product. Specifically, a discharging assembly 1, a correction guiding assembly 2, a guiding driving assembly 3, a sleeve cutting assembly 4 and a sleeve positioning assembly 5 are arranged, wherein the discharging assembly 1 is used for discharging a sleeve; the correction guide assembly 2 is used for correcting and guiding the sleeve discharged by the discharging assembly 1; the guiding driving assembly 3 comprises a driving roller 31, a driven roller 32 and a driving module 33 for driving the driving roller 31, wherein the driving module 33 is used for driving the driving roller 31 to rotate, and a gap for passing a sleeve is arranged between the driving roller 31 and the driven roller 32; the sleeve cutting assembly 4 comprises a guide pipe 41 connected to the lower side of the gap and a cutting module 42 positioned on the lower side of the guide pipe 41, wherein the guide pipe 41 is used for receiving a sleeve led in by the guide driving assembly 3, and the cutting module 42 is used for cutting the sleeve; the sleeve positioning assembly 5 comprises a lifting module 51 and a clamping module 52 connected to the lifting module 51, wherein the clamping module 52 is used for clamping the cut sleeve and sleeving the cut sleeve on the electronic component under the action of the lifting module 51. The sleeve can be automatically sleeved on the electronic element after being corrected and guided, so that the automatic sleeve of the electronic element is realized, the automatic sleeve is realized, the labor is saved, the automation degree is high, and the working efficiency is high.

The foregoing examples illustrate only a few embodiments of the utility model, which are described in detail and are not to be construed as limiting the scope of the utility model. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the utility model, which are all within the scope of the utility model. Accordingly, the scope of protection of the present utility model is to be determined by the appended claims.

Claims (10)

1. An electronic component bushing apparatus, characterized in that: comprising

The discharging assembly is used for discharging the sleeve;

the correction guide assembly is used for correcting and guiding the sleeve discharged by the discharging assembly;

the guide driving assembly comprises a driving roller, a driven roller and a driving module for driving the driving roller, wherein the driving module is used for driving the driving roller to rotate, and a gap for a sleeve to pass through is formed between the driving roller and the driven roller;

the sleeve cutting assembly comprises a guide pipe connected to the lower side of the gap and a cutting module positioned on the lower side of the guide pipe, the guide pipe is used for receiving the sleeve led in by the guide driving assembly, and the cutting module is used for cutting the sleeve;

the sleeve positioning assembly comprises a lifting module and a clamping module connected with the lifting module, and the clamping module is used for clamping the cut sleeve and sleeving the cut sleeve on the electronic element under the action of the lifting module;

the correction guide assembly comprises a correction seat and a guide seat, wherein the correction seat is arranged above the guide seat and used for conveying the corrected sleeve into the guide seat;

the correction seat is provided with a correction groove, the wall surface of the correction groove is symmetrically provided with a V-shaped groove, and one side of the V-shaped groove is provided with a feeding sensor;

the guide seat is provided with a slot, the slot is provided with a guide block in a inserted mode, the guide block is provided with a guide groove, the guide groove is provided with an expansion opening towards the correction groove, and the correction groove is a flat pull groove.

2. The electronic component bushing apparatus according to claim 1, wherein: the clamping module is used for clamping the cut sleeve and sleeved on the electronic element clamped by the clamping jaw under the action of the lifting module.

3. The electronic component bushing apparatus according to claim 1, wherein: the discharging assembly comprises a supporting frame, a discharging support arranged at the top end of the supporting frame and a discharging disc arranged on the discharging support, wherein the discharging support is provided with a tension roller, and the discharging disc is used for discharging a sleeve;

the support frame includes L type support, connects in the installation panel of L type support, correct guiding component, direction drive assembly, sleeve pipe blank subassembly and sleeve pipe locating component all install on the installation panel.

4. The electronic component bushing apparatus according to claim 1, wherein: one side of the driving roller is provided with a driving gear, one side of the driven roller is provided with a driven gear, the driving gear is used for meshing with the driven gear, the driving module is used for driving the driving gear and the driving roller to synchronously drive, and when the driven gear is meshed with the driving gear, the driven roller follows the driving roller to rotate and drive.

5. The electronic component bushing apparatus according to claim 4, wherein: the driven roller is connected with a sliding block, the sliding block is connected with a moving cylinder, and the moving cylinder is used for driving the sliding block to drive the driven roller to move towards the position of the driving roller and enabling the driven gear to be meshed with the driving gear.

6. The electronic component bushing apparatus according to claim 1, wherein: the guide pipe comprises a feeding head and a discharging head, concave cambered surfaces are symmetrically arranged on two sides of the feeding head, the concave cambered surfaces correspond to the driving roller and the driven roller respectively, and the discharging head is used for connecting the cutting-off module.

7. The electronic component bushing apparatus according to claim 6, wherein: the cutting-off module comprises a cutter support, a cutter cylinder arranged at one end of the cutter support, a movable block connected with the cutter cylinder and movable in the cutter support, and a sleeve cutter connected with the movable block, wherein a cutter edge of the sleeve cutter is abutted to the lower surface of the cutter support, and the discharge head is fixed at one end of the cutter support and corresponds to the cutter edge of the sleeve cutter at the discharge hole.

8. The electronic component bushing apparatus according to claim 1, wherein: the lifting module is a sliding table cylinder, the driving end of the lifting module is connected with an L-shaped block, the clamping module is arranged on the lower surface of the L-shaped block, the upper surface of the L-shaped block is provided with a pressing die set, and the pressing die set is used for pressing the sleeve into the electronic element;

the pressing module comprises a pressing cylinder and a pressing block connected to the pressing cylinder, and the pressing block is used for pressing the sleeve into the electronic component.

9. The electronic component bushing apparatus according to claim 1, wherein: the clamping module comprises a clamping cylinder and a clamping claw connected to the clamping cylinder, and the clamping claw is used for clamping the sleeve.

10. The electronic component bushing apparatus according to claim 9, wherein: the clamping claw comprises clamping plates which are symmetrical to each other, a positioning hole and a positioning pin are formed after the clamping plates are combined, the positioning hole is used for positioning pins of the electronic element, the positioning pin is used for positioning a sleeve, and one end of the positioning hole penetrates through the positioning pin.