CN113650194A

CN113650194A - Automatic feeding equipment for injection molding embedded parts

Info

Publication number: CN113650194A
Application number: CN202111005757.6A
Authority: CN
Inventors: 蓝博
Original assignee: Foshan Hehong Taiye Technology Co ltd
Current assignee: Foshan Hehong Taiye Technology Co ltd
Priority date: 2021-08-30
Filing date: 2021-08-30
Publication date: 2021-11-16

Abstract

The invention discloses automatic feeding equipment for injection molding of embedded parts, which comprises a turntable mechanism, a feeding mechanism and a control mechanism, wherein the turntable mechanism is fixed on a workbench and comprises a rotating device and a turntable, at least two lower dies are correspondingly arranged on the turntable, the feeding mechanism comprises a feeding mechanism, a material storing mechanism, a material moving mechanism and a material taking and placing mechanism, a vibrating disc of the feeding mechanism conveys the embedded parts to a material storing groove of the material storing mechanism, the material moving mechanism conveys the material taking and placing mechanism which absorbs the embedded parts to the upper part of one lower die through a screw rod slider module, and then the material taking and placing mechanism completes an automatic feeding process. This automatic feeding equipment's advantage lies in: the whole feeding process of the injection molding embedded part does not need manual participation, the automation degree is high, and the production efficiency is improved.

Description

Automatic feeding equipment for injection molding embedded parts

Technical Field

The invention relates to the technical field of mobile phone accessory production equipment, in particular to automatic feeding equipment for injection molding embedded parts.

Background

At present, many mobile phone injection molding parts need pre-burying injection molding. The pre-embedded injection molding is a method of fixing pre-embedded parts at proper positions in a mold in advance and then injecting plastic for molding. Most of embedded parts of the mobile phone injection molding parts are metal sheets, and the size is small. Present mill generally adopts the mode of artifical material loading, and this kind of mode production efficiency is low, and the cost of labor is high, and for improving injection efficiency, injection mold generally adopts many caves pore structure moreover, and the quality of product, the quantity of material loading and the life of mould are difficult to guarantee in artifical material loading.

Disclosure of Invention

The invention aims to provide automatic feeding equipment for injection molding of an embedded part, which solves the problem of low feeding efficiency of the embedded part.

In order to achieve the purpose, the invention adopts the following technical scheme:

an automatic feeding equipment of injection molding built-in fitting, includes: the rotary table mechanism, the feeding mechanism and the control mechanism are arranged above the workbench; the turntable mechanism comprises a rotating device fixed on the workbench and a horizontal turntable connected with the rotating device, and at least two lower dies are correspondingly arranged on the turntable; the feeding mechanism comprises a feeding mechanism, a material storing mechanism, a material moving mechanism and a material taking and placing mechanism, the material taking and placing mechanism is arranged above a lower die on the turntable, the material moving mechanism is arranged on one side of the material taking and placing mechanism, the direction from the material moving mechanism to the material taking and placing mechanism is in the X axial direction, and the material moving direction of the material moving mechanism is in the Y axial direction; the feeding mechanism comprises a vibrating disc fixed above the workbench, a discharge port of the vibrating disc is provided with a linear feeding channel, and a linear vibrating feeder is arranged below the linear feeding channel; the material storage mechanism comprises a first motor, a first screw rod and a first sliding block, the first screw rod and the first sliding block are fixed above the workbench, the first motor drives the first sliding block to move along an X axis, the first sliding block is fixed with the material storage device, and the upper part of the material storage device is provided with a material storage groove; the material moving mechanism comprises a second motor, a second screw rod and a second sliding block, the second screw rod and the second sliding block are fixed above the workbench, the second motor drives the second sliding block to move along the Y axis, and the second sliding block is connected with a material moving plate; the taking and placing mechanism comprises a Y-axis third motor connected with the material moving plate and a chute in the vertical direction, an eccentric wheel device is fixed on a shaft of the third motor, the eccentric wheel device is connected with a third sliding block matched with the chute, the third sliding block is fixed with the taking and placing device, a suction nozzle is arranged below the taking and placing device and corresponds to the material storage chute, and the suction nozzle is connected with a pneumatic switch; and the control mechanism is respectively connected with the turntable mechanism and the feeding mechanism.

Furthermore, an air groove is formed above a linear feeding channel of the feeding mechanism, an air blowing pipe is arranged above the air groove, and the air blowing direction of the air blowing pipe is consistent with the feeding direction of the linear feeding channel.

Furthermore, a material-containing induction column connected with the control mechanism is arranged at the tail end of the material storage groove of the material storage mechanism along the feeding direction.

Furthermore, a trumpet-shaped guide inclined plane is arranged at the initial end of the material storage groove of the material storage mechanism along the feeding direction.

Furthermore, an induction block is fixed on the third sliding block side of the pick-and-place mechanism, when the third sliding block slides to the top end, the induction block is matched with a first inductor fixed on the material moving plate, and the first inductor is connected with the control mechanism.

Furthermore, the taking and placing device is provided with a positioning pin in the vertical direction, and a positioning hole corresponding to the positioning pin is formed in the material storing device of the material storing mechanism.

Furthermore, the feeding mechanism is provided with a plurality of linear feeding channels, and the number of material storage grooves of the material storage mechanism is in a multiple relation with the number of the linear feeding channels.

Furthermore, the two lower dies on the turntable are arranged at an angle of 180 degrees relative to the rotating shaft of the turntable.

Further, rotary device includes the motor group, and the output shaft of motor group is equipped with the cam, corresponds with the cam and is equipped with the second inductor, and the second inductor is connected with control mechanism.

Furthermore, the control mechanism further comprises a third sensor and a warning lamp which are fixed at one end of the workbench.

The automatic feeding device comprises a rotary table mechanism, a feeding mechanism and a control mechanism, wherein the rotary table mechanism is fixed on a workbench and comprises a rotating device and a rotary table, at least two lower dies are correspondingly arranged on the rotary table, the feeding mechanism comprises a feeding mechanism, a material storing mechanism, a material moving mechanism and a material taking and placing mechanism, a vibrating disc of the feeding mechanism conveys embedded parts to a material storing groove of the material storing mechanism, the material moving mechanism conveys the material taking and placing mechanism which absorbs the embedded parts to the upper part of one lower die through a screw rod sliding block module, and then the material taking and placing mechanism completes an automatic feeding process. This automatic feeding equipment's advantage lies in: the whole feeding process of the injection molding embedded part does not need manual participation, the automation degree is high, and the production efficiency is improved.

Drawings

FIG. 1 is a schematic perspective view of an automatic feeding device for injection molding of embedded parts according to the present invention;

FIG. 2 is a schematic perspective view of a feeding mechanism of an automatic feeding device for injection molding of embedded parts, provided by the invention;

FIG. 3 is a schematic perspective view of a material storage mechanism of an automatic feeding device for injection molding of an embedded part according to the present invention;

FIG. 4 is a top view of a material storage device of an automatic feeding device for injection molding of embedded parts, provided by the invention;

FIG. 5 is a schematic perspective view of a material moving mechanism of an automatic feeding device for injection molding of an embedded part, provided by the invention;

FIG. 6 is a schematic perspective view of a pick-and-place mechanism of an automatic feeding device for injection molding of an embedded part, provided by the invention;

FIG. 7 is an exploded view of the assembly of the locating pin of the automatic feeding device for injection molding of an embedded part according to the present invention;

fig. 8 is a partial enlarged view of fig. 1 at a.

Detailed Description

The invention provides automatic feeding equipment for injection molding embedded parts, which is further described in detail below by referring to the attached drawings and embodiments in order to make the purposes, technical schemes and effects of the invention clearer and clearer. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

The invention provides automatic feeding equipment for injection molding embedded parts, which is structurally shown in figures 1-8 and comprises: a worktable 10 and a turntable mechanism 20, a feeding mechanism 30 and a control mechanism 40 arranged above the worktable 10.

The turntable mechanism 20 comprises a rotating device 21 fixed on the workbench and a horizontal turntable 22 connected with the rotating device 21, at least two lower dies 23 are correspondingly arranged on the turntable 22, one feeding lower die 231 is used for feeding, one end of the feeding lower die 231 is provided with a feeding mechanism 30, and the other injection lower die 232 is used for injection molding.

The feeding mechanism 30 comprises a feeding mechanism 31, a material storing mechanism 32, a material moving mechanism 33 and a material taking and placing mechanism 34, the material taking and placing mechanism 34 is arranged above a feeding lower die 231 on the turntable 22, the material moving mechanism 33 is arranged on one side of the material taking and placing mechanism 34, the direction from the material moving mechanism 33 to the material taking and placing mechanism 34 is in the X axial direction, and the material moving direction of the material moving mechanism 33 is in the Y axial direction.

The feeding mechanism 31 comprises a vibration disc 311 fixed above the workbench 10, a linear feeding channel 312 is arranged at a discharge port of the vibration disc 311, a linear vibration feeder 313 is arranged below the linear feeding channel 312, and embedded parts enter the linear feeding channel 312 in sequence after being subjected to vibration sequencing by the vibration disc 311.

The material storage mechanism 32 comprises a first motor 321, a first screw rod 322 and a first sliding block 323, wherein the first screw rod 322 and the first sliding block 323 are fixed above the workbench 10, the first motor 321 drives the first sliding block 323 to move along the X axis through a coupler, the first sliding block 323 is fixed with the material storage device 324, the material storage device 324 reciprocates along the X axis along with the first sliding block 323, a material storage groove 325 is arranged at the upper part of the material storage device 324, and when the first sliding block 323 drives the material storage device 324 to move to the tail end of a linear feeding channel 312 of the feeding mechanism 31, the linear vibration feeder 313 conveys the embedded part to the material storage groove 325 along the linear feeding channel 312.

The material moving mechanism 33 comprises a second motor 331, a second screw rod 332 and a second sliding block 333, the second screw rod 332 and the second sliding block 333 are fixed above the workbench 10, the second motor 331 drives the second sliding block 333 to move along the Y axis through a coupler, and the second sliding block 333 is connected with a material moving plate 334.

The pick-and-place mechanism 34 comprises a third motor 341 in the Y-axis direction and connected with the material moving plate 334, and a chute 342 in the vertical direction, an eccentric wheel device 343 is fixed on a shaft of the third motor, the eccentric wheel device 343 is connected with a third slider 344 matched with the chute 342, the third slider 344 is fixed with the pick-and-place device 345, the third slider 344 reciprocates up and down along with the rotation of the third motor 341 to drive the pick-and-place device 345 to reciprocate up and down, a suction nozzle 345a is arranged below the pick-and-place device 345 and corresponds to the material storage tank 325, the suction nozzle 345a is connected with a pneumatic switch 346, and the pneumatic switch 346 controls the air pressure in the suction nozzle 345a to suck or place the embedded parts in the material storage tank 325.

The control mechanism 40 is connected to the turntable mechanism 20 and the feeding mechanism 30 respectively.

When the first sliding block 323 drives the material storage device 324 to move to the tail end of the linear feeding channel 312 of the feeding mechanism 31, the embedded part is conveyed to the material storage groove 325 along the linear feeding channel 312, then the material storage device 324 is conveyed to the initial position of the material moving mechanism 33 along the X axis by the first sliding block 323, the picking and placing mechanism 34 connected with the material moving plate 334 moves downwards, the embedded part of the material storage device 324 is sucked by the suction nozzle 345a, the picking and placing mechanism 34 continues to move upwards, the picking and placing mechanism 34 moves downwards again along with the movement of the material moving plate 334 to the position above the injection lower die 232 along the Y axis until the embedded part reaches the embedded position of the loading lower die 231, the suction nozzle 345a releases the embedded part and then moves upwards, and then the cycle of the next loading process is started. The control mechanism 40 logically controls the electrical systems of the turntable mechanism 20 and the feed mechanism 30.

Specifically, an air groove 314 is arranged above a linear feeding channel 312 of the feeding mechanism 31, an air blowing pipe 315 is arranged above the air groove 314, the air blowing direction of the air blowing pipe 315 is consistent with the feeding direction of the linear feeding channel 312, and the air blowing pipe 315 blows air to an embedded part in the linear feeding channel 312, so that feeding is smoother, and the accumulation phenomenon is avoided.

Specifically, a material-containing induction column 326 connected with the control mechanism 40 is arranged at the tail end of the material storage groove 325 of the material storage mechanism 32 along the feeding direction, and the material-containing induction column 326 is used for inducing whether the embedded part reaches the tail end of the material storage groove 325. The material storage tank 325 is provided with a through hole 325a in the vertical direction, the material sensing column 326 is arranged right above the through hole 325a, and when the embedded part reaches the tail end of the material storage tank 325, the material sensing column 326 transmits a signal to the control system 40 so as to logically control the first motor 321 for driving the material storage tank 325 to move.

Specifically, a trumpet-shaped guide inclined surface 325b is arranged at the starting end of the material storage groove 325 of the material storage mechanism 32 in the feeding direction, so that even if an error exists between the position of the material storage groove 325 and the position of the linear feeding channel 312 in the moving process, the guide inclined surface 325b can enable the embedded part to be smoothly conveyed into the material storage groove 325.

Specifically, the sensing block 347 is fixed to the third slider 344 of the pick-and-place mechanism 34, and when the third slider 344 slides to the top end, the sensing block 347 is matched with the first sensor 348 fixed to the material moving plate 334, and the first sensor 348 is connected to the control mechanism 40. When the third slider 344 slides to the top, the pick-and-place device 345 is completely separated from the feeding lower mold 231 or the material storing mechanism 32, the first sensor 348 simultaneously transmits signals to the control system 40, and the control system 40 can logically control the turntable mechanism 20 and the material transferring mechanism 33.

Specifically, the taking and placing device 345 is provided with a positioning pin 349 in the vertical direction, and the storing device 324 of the storing mechanism 32 is provided with a positioning hole 324a corresponding to the positioning pin 349. When the pick-and-place device 345 moves to the material storage mechanism 32, the positioning pin 349 slides down into the positioning hole 324a, the positioning pin 349 is generally set to be in a tip positioning mode, when the pick-and-place device 345 approaches to the material storage mechanism 32, the tip of the positioning pin 349 enters the positioning hole 324a until the positioning pin 349 completely slides down into the positioning hole 324a, and the suction nozzle 345a of the pick-and-place device 345 moves right above the material storage groove 325, so that the position accuracy of material taking is ensured, and the situation that the suction nozzle 345a cannot effectively suck the embedded part 50 is avoided.

Specifically, the feeding mechanism 31 is provided with a plurality of linear feeding channels 312, and the number of the material storage slots 325 of the material storage mechanism 32 is in a multiple relation with the number of the linear feeding channels 312. As shown in fig. 1 to 8, the number of the linear feeding channels 312 is 4, and the number of the material storage grooves 325 is 8, so that the feeding efficiency is improved. Similarly, the number of the cavities of the suction nozzle 345a and the lower die 23 of the pick-and-place device 345 can be set to be in a multiple relation with the number of the linear feeding channels 312, so that the feeding efficiency is improved as a whole.

Specifically, the two lower dies 23 on the turntable 22 are arranged at 180 ° relative to the rotation axis of the turntable 22. Lower mould 23 can all be arranged to 4 directions on the workstation 10 horizontal plane, and the lower mould 232 of moulding plastics is in the one end of workstation 10, and material loading lower mould 231 sets up at the other end relative with the lower mould 232 of moulding plastics, and material loading process is carried out to material loading lower mould 231 one side, and the lower mould 232 of moulding plastics simultaneously moulds plastics the process, and the staff can maintain equipment in other directions of lower mould 23.

Specifically, the rotating device 21 includes a motor set 211, a cam 212 is disposed on an output shaft 211a of the motor set 211, a second sensor 213 is disposed corresponding to the cam 212, and the second sensor 213 is connected to the control mechanism 40. As shown in fig. 1-8, as the output shaft 211a rotates, 1/4 circles of the cam 212 along the circumferential direction may contact the second sensor 213 that is adjustable in the lateral direction, and 3/4 circles of the cam may not contact the second sensor 213, so that a signal may be intermittently transmitted to the control mechanism 40, and the control mechanism 40 may control the rotating device 21 to intermittently rotate the turntable 22, thereby ensuring that the turntable 22 does not rotate during the loading period.

Specifically, the control mechanism 40 further includes a third sensor 41 and a warning light 42 fixed at one end of the worktable 10. As shown in fig. 1 to 8, the third sensor 41 and the warning light 42 are disposed on one side of the injection molding lower mold 232, the third sensor 41 is vertically disposed on two sides of the workbench 10, if someone is present in the sensing range of the third sensor 41, the warning light 42 immediately gives an alarm, and the third sensor 41 sends a signal to the control mechanism 40 to interrupt a corresponding process, so as to ensure the safety of the operation of the device.

In summary, the present invention includes a turntable mechanism 20 fixed on a worktable 10, a feeding mechanism 30 and a control mechanism 40, the turntable mechanism 20 includes a rotating device 21 and a turntable 22, at least two lower molds 23 are correspondingly disposed on the turntable 22, the feeding mechanism 30 includes a feeding mechanism 31, a storage mechanism 32, a transferring mechanism 33 and a pick-and-place mechanism 34, a vibrating plate 311 of the feeding mechanism 31 transfers the embedded parts to a storage tank 325 of the storage mechanism 32, the transferring mechanism 33 transfers the pick-and-place mechanism 34, which has sucked the embedded parts, to a position above one of the lower molds through a screw slider module, and then the pick-and-place mechanism 34 completes an automatic feeding process. This automatic feeding equipment's advantage lies in: the whole feeding process of the injection molding embedded part does not need manual participation, the automation degree is high, and the production efficiency is improved.

It will be understood that modifications and variations can be made by persons skilled in the art in light of the above teachings and all such modifications and variations are intended to be included within the scope of the invention as defined in the appended claims.

Claims

1. The utility model provides an automatic feeding equipment of built-in fitting of moulding plastics which characterized in that includes: the rotary table mechanism, the feeding mechanism and the control mechanism are arranged above the workbench;

the turntable mechanism comprises a rotating device fixed on the workbench and a horizontal turntable connected with the rotating device, and at least two lower dies are correspondingly arranged on the turntable;

the feeding mechanism comprises a feeding mechanism, a material storing mechanism, a material moving mechanism and a material taking and placing mechanism, the material taking and placing mechanism is arranged above a lower die on the turntable, the material moving mechanism is arranged on one side of the material taking and placing mechanism, the direction from the material moving mechanism to the material taking and placing mechanism is in the X axial direction, and the material moving direction of the material moving mechanism is in the Y axial direction;

the feeding mechanism comprises a vibrating disc fixed above the workbench, a discharge port of the vibrating disc is provided with a linear feeding channel, and a linear vibrating feeder is arranged below the linear feeding channel;

the material storage mechanism comprises a first motor, a first screw rod and a first sliding block, the first screw rod and the first sliding block are fixed above the workbench, the first motor drives the first sliding block to move along an X axis, the first sliding block is fixed with the material storage device, and the upper part of the material storage device is provided with a material storage groove;

the material moving mechanism comprises a second motor, a second screw rod and a second sliding block, the second screw rod and the second sliding block are fixed above the workbench, the second motor drives the second sliding block to move along the Y axis, and the second sliding block is connected with a material moving plate;

the taking and placing mechanism comprises a Y-axis third motor connected with the material moving plate and a chute in the vertical direction, an eccentric wheel device is fixed on a shaft of the third motor, the eccentric wheel device is connected with a third sliding block matched with the chute, the third sliding block is fixed with the taking and placing device, a suction nozzle is arranged below the taking and placing device and corresponds to the material storage chute, and the suction nozzle is connected with a pneumatic switch;

and the control mechanism is respectively connected with the turntable mechanism and the feeding mechanism.

2. The automatic feeding equipment for injection molding of embedded parts according to claim 1, characterized in that: the air blowing mechanism is characterized in that an air groove is formed above a linear feeding channel of the feeding mechanism, an air blowing pipe is arranged above the air groove, and the air blowing direction of the air blowing pipe is consistent with the feeding direction of the linear feeding channel.

3. The automatic feeding equipment for injection molding of embedded parts according to claim 1, characterized in that: and a material induction column connected with the control mechanism is arranged at the tail end of the material storage groove of the material storage mechanism along the feeding direction.

4. The automatic feeding equipment for injection molding of embedded parts according to claim 1, characterized in that: the initial end of the material storage groove of the material storage mechanism along the feeding direction is provided with a trumpet-shaped guide inclined plane.

5. The automatic feeding equipment for injection molding of embedded parts according to claim 1, characterized in that: and an induction block is fixed on the third sliding block side of the pick-and-place mechanism, and when the third sliding block slides to the top end, the induction block is matched with a first inductor fixed on the material moving plate, and the first inductor is connected with the control mechanism.

6. The automatic feeding equipment for injection molding of embedded parts according to claim 1, characterized in that: the taking and placing device is provided with a positioning pin in the vertical direction, and a positioning hole corresponding to the positioning pin is formed in the material storing device of the material storing mechanism.

7. The automatic feeding equipment for injection molding of embedded parts according to claim 1, characterized in that: the feeding mechanism is provided with a plurality of linear feeding channels, and the number of material storage grooves of the material storage mechanism is in a multiple relation with the number of the linear feeding channels.

8. The automatic feeding equipment for injection molding of embedded parts according to claim 1, characterized in that: the two lower dies on the turntable are arranged at an angle of 180 degrees relative to the rotating shaft of the turntable.

9. The automatic feeding equipment for injection molding of embedded parts according to claim 1, characterized in that: the rotating device comprises a motor set, a cam is arranged on an output shaft of the motor set, a second inductor is arranged corresponding to the cam, and the second inductor is connected with the control mechanism.

10. The automatic feeding equipment for injection molding of embedded parts according to claim 1, characterized in that: the control mechanism further comprises a third sensor and a warning lamp which are fixed at one end of the workbench.