CN116060541A

CN116060541A - Triode pin former

Info

Publication number: CN116060541A
Application number: CN202310067862.5A
Authority: CN
Inventors: 焦庆
Original assignee: Semtech Semiconductor Technology Dongguan Co Ltd
Current assignee: Semtech Semiconductor Technology Dongguan Co Ltd
Priority date: 2023-01-13
Filing date: 2023-01-13
Publication date: 2023-05-05

Abstract

The utility model provides triode pin forming equipment which comprises two forming and placing mechanisms, two forming and cutting mechanisms and a collecting tray, wherein the two forming and placing mechanisms are adjacently arranged, and the forming and cutting mechanisms are correspondingly arranged on the other sides of the two forming and placing mechanisms respectively; the material collecting tray is arranged right below the two forming and placing mechanisms; the molding and placing mechanism comprises a triode shell placing seat and a rotary driving motor, wherein two opposite sides of the triode shell placing seat in the width direction are connected with a vertical plate on the workbench through a rotating shaft; a rotary driving motor is arranged on one side vertical plate, and the power output end of the rotary driving motor is in power connection with one side rotating shaft; the forming and cutting mechanism comprises a forming seat, a cutting driving motor, a cutter and two linear motors. And the production efficiency is improved.

Description

Triode pin former

Technical Field

The utility model relates to the technical field of triode processing, in particular to triode pin forming equipment.

Background

The Chinese authorized bulletin number is CN 215746076U, and the authorized bulletin day is 2022, 02 and 08, and the triode pin shearing and bending device is provided, and concretely relates to numerical control lathe field comprises a base, the top fixed mounting of base has the pillar, the top fixed mounting of pillar has the fixed station, the top fixed mounting of fixed station has the processing platform. According to the utility model, the pushing cylinder, the pressing punch assembly and the infrared induction sensor are arranged, after the triode is pushed to the corresponding position by the pushing mechanism, the pressing main cylinder is pressed downwards, the pressing punch assembly is pushed downwards by the connecting rod, the bending upper punch at the bottom end of the pressing punch assembly is driven to bend the triode on the processing table, the pressing main cylinder is pressed downwards, the shearing upper punch at the bottom end of the pressing punch assembly can move downwards, redundant pins of the triode are cut off, the shearing and bending procedures are completed simultaneously, the cutting and shaping actions are completed once, and the device has the characteristics of high efficiency, high shearing and bending precision, good consistency, no personnel participation and the like. The prior art has the following defects: the triode after the shaping needs the people hand to take away, can not realize automatic receipts material, influences production efficiency.

Disclosure of Invention

Based on the above, the utility model aims to provide triode pin forming equipment, which improves the production efficiency.

The utility model provides triode pin forming equipment which comprises two forming and placing mechanisms, two forming and cutting mechanisms and a collecting tray, wherein the two forming and placing mechanisms are adjacently arranged, and the forming and cutting mechanisms are correspondingly arranged on the other sides of the two forming and placing mechanisms respectively; the material collecting tray is arranged right below the two forming and placing mechanisms;

the molding and placing mechanism comprises a triode shell placing seat and a rotary driving motor, wherein two opposite sides of the triode shell placing seat in the width direction are connected with a vertical plate on the workbench through a rotating shaft; a rotary driving motor is arranged on one side vertical plate, and the power output end of the rotary driving motor is in power connection with one side rotating shaft;

the forming and cutting mechanism comprises a forming seat, a cutting driving motor, a cutter and two linear motors, wherein the forming seat is transversely arranged between the two linear motors and corresponds to the triode tube shell placing seat in position, and two opposite sides of the forming seat in the width direction are respectively connected with sliding seats of the two linear motors through connecting blocks; and a support is arranged between the two connecting blocks, a cutting driving motor is arranged in the middle of the upper surface of the support, and the power output end of the cutting driving motor is arranged to extend towards one side of the forming seat and is connected with the cutter.

As a preferred scheme, the upper surface of triode tube housing seat is formed with a triode tube housing jogging groove along its length direction, triode tube housing seat lean on adjacent one side shaping cutting mechanism's side be formed with a plurality of with triode tube housing jogging groove intercommunication and supply triode pin to stretch out the pin spacing groove.

Preferably, a plurality of molding cavities corresponding to the triode shell embedding grooves are formed on one side of the upper surface of the molding seat, which is close to the triode shell placing seat; the upper surface of the forming seat is provided with a cutting groove which is communicated with the forming cavity and is used for inserting the cutter.

As a preferable scheme, a mounting groove communicated with the cutting groove is formed in the lower part of one side of the forming seat far away from the forming cavity, and a waste collecting disc is movably placed in the mounting groove.

As a preferable scheme, an auxiliary discharging mechanism is arranged between the two forming and placing mechanisms; the auxiliary discharging mechanism comprises a U-shaped bracket, a lifting driving motor and an I-shaped pressing part; the lifting driving motor is correspondingly arranged in the middle of the upper surface of the U-shaped bracket, and the power output end of the lifting driving motor extends downwards and is connected with the middle of the upper surface of the I-shaped material pressing part; the opposite sides of the I-shaped material pressing part correspond to the positions of the triode tube housing placing seats on the two sides respectively.

As the preferable scheme, the upper portions of two opposite sides of the I-shaped material pressing part are connected with a mounting plate through an inverted L-shaped workpiece, a plurality of air blowing nozzles corresponding to the triode tube shell placing seat are arranged on the mounting plate, and the air blowing nozzles are connected with an air source through a pipeline.

Preferably, a conveyer belt for conveying the material collecting tray is arranged below the two forming and placing mechanisms.

The beneficial effects of the utility model are as follows: through setting up two shaping and placing the mechanism, two shaping cut mechanism, a collection tray, can realize that both sides carry out the shaping of bending of triode simultaneously, cut the operation, the triode is directly poured into the collection tray behind the rotatory 180 of rethread triode tube shell placing seat to improve production efficiency.

Drawings

Fig. 1 is a perspective view of the present utility model.

The reference numerals are: the conveyer belt 10, mounting groove 11, shaping seat 12, shaping chamber 13, linear electric motor 14, pin spacing groove 15, triode tube housing seat 16, triode tube housing chimeric groove 17, U-shaped support 18, worker shape swage portion 19, blowing nozzle 20, inverted L-shaped work piece 22, mounting panel 21, lift driving motor 23, cut driving motor 24, cutter 26, rotary driving motor 25, cut groove 27, collection tray 28, support 29, connecting block 30, pivot 31, riser 32.

Detailed Description

The utility model will be further described in detail with reference to the following detailed description and the accompanying drawings, in order to further understand the features and technical means of the utility model and the specific objects and functions achieved.

In the present utility model, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and include, for example, either permanently connected, removably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

Referring to fig. 1, the present utility model provides a triode pin forming apparatus, which includes two forming and placing mechanisms, two forming and cutting mechanisms, and a collecting tray 28, wherein the two forming and placing mechanisms are adjacently arranged, and the forming and cutting mechanisms are correspondingly arranged at the other sides of the two forming and placing mechanisms respectively; the material collecting tray 28 is arranged right below the two forming and placing mechanisms; the conveyer belt 10 for conveying the material collecting tray 28 is arranged below the two forming and placing mechanisms, so that the material collecting tray can be automatically input and output without manually replacing the material collecting tray 28.

The forming and placing mechanism comprises a triode shell placing seat 16 and a rotary driving motor 25, and two opposite sides of the triode shell placing seat 16 in the width direction are connected with a vertical plate 32 on the workbench through a rotating shaft 31; a rotation driving motor 25 is mounted on the one side vertical plate 32, and a power output end of the rotation driving motor 25 is in power connection with the one side rotating shaft 31. The upper surface of the triode tube housing seat 16 is provided with a triode tube housing embedding groove 17 along the length direction thereof, and the side surface of the triode tube housing seat 16, which is close to the adjacent side forming cutting mechanism, is provided with a plurality of pin limiting grooves 15 which are communicated with the triode tube housing embedding groove 17 and are used for extending triode pins.

The forming and cutting mechanism comprises a forming seat 12, a cutting driving motor 24, a cutter 26 and two linear motors 14, wherein the forming seat 12 is transversely arranged between the two linear motors 14 and corresponds to the triode tube shell placing seat 16 in position, and two opposite sides of the forming seat 12 in the width direction are respectively connected with sliding seats of the two linear motors 14 through connecting blocks 30; a bracket 29 is arranged between the two connecting blocks 30, a cutting driving motor 24 is arranged in the middle of the upper surface of the bracket 29, and the power output end of the cutting driving motor 24 is extended towards one side of the forming seat 12 and is connected with a cutter 26. A plurality of molding cavities 13 corresponding to the triode shell embedding grooves 17 are formed on one side of the upper surface of the molding seat 12, which is close to the triode shell placing seat 16; the upper surface of the forming seat 12 is provided with a cutting groove 27 communicating with the forming cavity 13 along its length direction and into which the cutter 26 is inserted.

A mounting groove 11 communicated with the cutting groove 27 is formed at the lower part of one side of the forming seat 12 far away from the forming cavity 13, and a waste collecting disc is movably arranged in the mounting groove 11.

An auxiliary discharging mechanism is arranged between the two forming placing mechanisms; the auxiliary discharging mechanism comprises a U-shaped bracket 18, a lifting driving motor 23 and an I-shaped pressing part 19; the lifting driving motor 23 is correspondingly arranged in the middle of the upper surface of the U-shaped bracket 18, and the power output end of the lifting driving motor 23 extends downwards and is connected with the middle of the upper surface of the I-shaped material pressing part 19; the opposite sides of the I-shaped material pressing part 19 correspond to the positions of the triode tube housing placing seats 16 on the two sides respectively. Through such structure setting, when the triode is unloaded after the triode tube is placed seat 16 and is rotated 180, avoid the triode to stay in triode tube gomphosis groove 17, press the pin contact of material portion 19 and triode and press the triode to breaking away from triode tube gomphosis groove 17 through the worker to ensure that the shaping action of next time can normally develop.

The upper parts of the two opposite sides of the I-shaped material pressing part 19 are connected with mounting plates 21 through inverted L-shaped workpieces 22, a plurality of air blowing nozzles 20 corresponding to the triode tube housing placing seats 16 are arranged on the mounting plates 21, and the air blowing nozzles 20 are connected with an air source through pipelines. Through the structure, the triode tube housing embedding groove 17 can be cleaned by blowing air at regular intervals, so that the triode tube housing embedding groove 17 is kept clean, and the quality of products is ensured.

The utility model comprises the following operation steps:

1. the triode is sequentially placed in the triode tube embedding groove 17, and pins of the triode penetrate out of the pin limiting groove 15;

2. the two linear motors 14 drive the forming seat 12 to move towards the triode shell placing seat 16 until the forming seat contacts with the triode shell placing seat 16, so that pins of the triode are correspondingly inserted into the forming cavity 13 to complete bending forming action;

3. the power output of the cutting driving motor 24 drives the cutter 26 to move towards the cutting groove 27 so as to complete the cutting action of the pins; collecting the residual pins after cutting through a waste collecting tray; the waste collection tray can be taken out for cleaning in a set time;

4. the two linear motors 14 drive the forming seat 12 to reset to the initial position;

5. the power output of the rotary driving motor 25 causes the triode tube housing seat 16 to rotate 180 degrees and then directly pours the triode into the collecting tray;

6. after the tray is full, the tray is conveyed to the corresponding position while the tray is empty by the conveyor belt 10, and the above operation is continuously repeated.

According to the utility model, by arranging the two forming and placing mechanisms, the two forming and cutting mechanisms and the collecting tray, the bending forming and cutting operation of the triode can be simultaneously carried out on two sides, and then the triode is directly poured into the collecting tray after the triode shell placing seat rotates 180 degrees, so that the production efficiency is improved.

The above examples illustrate only one embodiment of the utility model, which is described in more detail and is 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

1. Triode pin former, its characterized in that: the device comprises two shaping and placing mechanisms, two shaping and cutting mechanisms and a collecting tray (28), wherein the two shaping and placing mechanisms are adjacently arranged, and the shaping and cutting mechanisms are respectively and correspondingly arranged on the other sides of the two shaping and placing mechanisms; the material collecting plate (28) is arranged right below the two forming and placing mechanisms;

the molding and placing mechanism comprises a triode tube placing seat (16) and a rotary driving motor (25), wherein two opposite sides of the triode tube placing seat (16) in the width direction are connected with a vertical plate (32) on the workbench through a rotating shaft (31); a rotary driving motor (25) is arranged on the side vertical plate (32), and the power output end of the rotary driving motor (25) is in power connection with the side rotating shaft (31);

the forming and cutting mechanism comprises a forming seat (12), a cutting driving motor (24), a cutter (26) and two linear motors (14), wherein the forming seat (12) is transversely arranged between the two linear motors (14) and corresponds to the triode tube shell placing seat (16), and two opposite sides of the forming seat (12) in the width direction are connected with sliding seats of the two linear motors (14) through connecting blocks (30) respectively; a support (29) is arranged between the two connecting blocks (30), a cutting driving motor (24) is arranged in the middle of the upper surface of the support (29), and the power output end of the cutting driving motor (24) is arranged to extend towards one side of the forming seat (12) and is connected with the cutter (26).

2. The triode pin forming apparatus of claim 1, wherein: the upper surface of triode tube housing seat (16) is formed with a triode tube housing gomphosis groove (17) along its length direction, triode tube housing seat (16) lean on adjacent one side shaping cutting mechanism's side be formed with a plurality of with triode tube housing gomphosis groove (17) intercommunication and supply triode pin to stretch out pin spacing groove (15).

3. The triode pin forming apparatus of claim 2, wherein: a plurality of molding cavities (13) corresponding to the triode shell embedding grooves (17) are formed on one side, close to the triode shell placing seat (16), of the upper surface of the molding seat (12); the upper surface of the forming seat (12) is provided with a cutting groove (27) which is communicated with the forming cavity (13) along the length direction and is used for inserting the cutter (26).

4. A triode pin formation apparatus according to claim 3, wherein: the lower part of one side of the forming seat (12) far away from the forming cavity (13) is provided with a mounting groove (11) communicated with the cutting groove (27), and a waste collecting disc is movably arranged in the mounting groove (11).

5. A triode pin formation apparatus according to any one of claims 1 to 4, wherein: an auxiliary unloading mechanism is arranged between the two forming and placing mechanisms; the auxiliary discharging mechanism comprises a U-shaped bracket (18), a lifting driving motor (23) and an I-shaped pressing part (19); the lifting driving motor (23) is correspondingly arranged in the middle of the upper surface of the U-shaped bracket (18), and the power output end of the lifting driving motor (23) extends downwards and is connected with the middle of the upper surface of the I-shaped pressing part (19); opposite sides of the I-shaped material pressing part (19) are respectively corresponding to positions of the triode tube housing placing seats (16) at the two sides.

6. The triode pin forming apparatus of claim 5, wherein: the upper parts of two opposite sides of the I-shaped pressing part (19) are connected with a mounting plate (21) through inverted L-shaped workpieces (22), a plurality of air blowing nozzles (20) corresponding to the triode tube shell placing seat (16) are arranged on the mounting plate (21), and the air blowing nozzles (20) are connected with an air source through pipelines.

7. The triode pin formation apparatus of claim 6, wherein: a conveying belt (10) for conveying the material collecting tray (28) is arranged below the two forming and placing mechanisms.