CN221111988U

CN221111988U - Bidirectional automatic board dividing machine

Info

Publication number: CN221111988U
Application number: CN202323115953.6U
Authority: CN
Inventors: 杨伟伟; 李昌来
Original assignee: Dongguan Weichang Intelligent Technology Co ltd
Current assignee: Dongguan Weichang Intelligent Technology Co ltd
Priority date: 2023-11-17
Filing date: 2023-11-17
Publication date: 2024-06-11
Anticipated expiration: 2033-11-17

Abstract

The utility model relates to the technical field of circuit board production, in particular to a bidirectional automatic board dividing machine; comprises a first workbench and a plate separating device; the plate separating device is arranged on the first workbench and comprises a first conveying mechanism, a first conveying belt and a cutting mechanism, an upper hob and a lower hob are arranged on the cutting mechanism, the upper hob and the lower hob are oppositely arranged and are in transmission connection, and a rotating mechanism for driving the lower hob to rotate is arranged on the cutting mechanism; compared with the prior art, the cutting mechanism is divided into the transverse cutting mechanism and the longitudinal cutting mechanism, the transverse cutting mechanism and the longitudinal cutting mechanism are arranged, so that the function of cutting the circuit board in two directions can be realized, the circuit board does not need to be dismounted again and rotated in the cutting process, the labor force of workers is further reduced, the production time is saved, the production efficiency of equipment is greatly improved, large-scale production of enterprises is facilitated, and the practicability is high.

Description

Bidirectional automatic board dividing machine

Technical Field

The utility model relates to the technical field of circuit board production, in particular to a bidirectional automatic board dividing machine.

Background

The circuit board dividing machine is a fully automatic production device which is specially used for cutting, dividing and slitting various pcb circuit boards, led lamp strips, various circuit boards and linear circuit boards in the electronic production industry, and is used for replacing manual and high-speed industrial automation equipment for improving the production efficiency.

At present, the traditional board splitting machine generally can only cut one direction of a circuit board, for example, when the transverse direction of the circuit board is cut, the circuit board needs to be disassembled and rotated to be positioned, and then the circuit board is cut in the longitudinal direction, but the process not only needs to consume more labor force, but also has lower production efficiency when the two directions of the circuit board need to be cut, and is not beneficial to enterprises to carry out large-scale production; for this purpose, we propose a bi-directional automatic board separator.

Disclosure of utility model

Aiming at the defects of the prior art, the utility model provides a bidirectional automatic board dividing machine, which can realize the function of cutting a circuit board in two directions after improvement, thereby reducing the labor force of workers and greatly improving the production efficiency of equipment.

The technical scheme of the utility model is as follows:

A bidirectional automatic board dividing machine comprises a first workbench and a board dividing device; the plate separating device is arranged on the first workbench and comprises a first conveying mechanism, a first conveying belt and a cutting mechanism, an upper hob and a lower hob are arranged on the cutting mechanism, the upper hob and the lower hob are oppositely arranged and are in transmission connection, and a rotating mechanism for driving the lower hob to rotate is arranged on the cutting mechanism; the cutting mechanism is divided into a transverse cutting mechanism and a longitudinal cutting mechanism, and the transverse cutting mechanism is also connected with a driving mechanism for driving the upper hob and the lower hob to move back and forth;

The first conveyor belt is positioned between the transverse cutting mechanism and the longitudinal cutting mechanism, a first sucker is arranged at the moving end of the first conveying mechanism, the first conveying mechanism drives the first sucker to move to suck the workpiece on the feeding belt into the transverse cutting mechanism for transverse cutting processing, and drives the first sucker to move to suck the workpiece which is subjected to transverse cutting processing in the transverse cutting mechanism onto the first conveyor belt; the first conveyor belt is used for conveying the workpiece to the slitting mechanism for slitting.

Further, the first conveying mechanism further comprises a first X-axis linear module and a first lifting cylinder, the first X-axis linear module is fixedly connected to the first workbench, the moving end of the first X-axis linear module is fixedly connected with the first lifting cylinder, the push rod end of the first lifting cylinder is connected with a lifting column, the other end of the lifting column is fixedly connected with a first sucker, and the first sucker is communicated with a vacuum source.

Further, the side surface of the upper hob blade is contacted with the side surface of the lower hob blade to realize the transmission of the upper hob and the lower hob.

Further, a first objective table frame is further arranged on the transverse cutting mechanism and fixedly connected to the first workbench, the first objective table frame is located between the upper hob and the lower hob of the transverse cutting mechanism, a positioning pin is arranged on the first objective table frame and used for positioning and inserting workpieces, and a first hob groove penetrating through the upper hob and the lower hob of the transverse cutting mechanism is further formed in the first objective table frame, so that the top surface and the bottom surface of the workpieces are respectively contacted with the upper hob and the lower hob of the transverse cutting mechanism to realize cutting.

Further, a second objective table frame is further arranged on the slitting mechanism and fixedly connected to the first workbench, the second objective table frame is located between the upper hob and the lower hob of the slitting mechanism, and second hob grooves penetrating through the upper hob and the lower hob of the slitting mechanism are further formed in the second objective table frame, so that the top surface and the bottom surface of a workpiece are in contact with the upper hob and the lower hob of the slitting mechanism respectively to realize cutting.

Further, the rotating mechanism comprises a servo motor and a gear structure; the servo motor is arranged on the first workbench and is in transmission connection with the gear structure, and the rotating end of the gear structure is fixedly connected with the lower hob.

Further, the plate separating device further comprises a second conveying belt and a second conveying mechanism, wherein the second conveying belt and the second conveying mechanism are positioned at the rear side of the slitting mechanism, and the second conveying belt is used for receiving the workpiece slit by the slitting mechanism; the second conveying mechanism comprises a second X-axis linear module, a second lifting cylinder and a second sucker, wherein the second X-axis linear module is fixedly connected to the first workbench, the moving end of the second X-axis linear module is fixedly connected with the second lifting cylinder, the push rod end of the second lifting cylinder is fixedly connected with the second sucker, and the second sucker is communicated with the vacuum source.

Further, the board separator also comprises a second workbench and a swinging plate device; the swinging disc device is arranged on the second workbench and comprises a third conveying mechanism, a third conveying belt and a swinging disc seat, wherein the third conveying belt and the swinging disc seat are respectively arranged on the second workbench, the third conveying mechanism comprises an XYZ-axis linear module, a third lifting cylinder and a third sucker, the XYZ-axis linear module is fixedly connected to the second workbench, the moving end of the XYZ-axis linear module is fixedly connected with the third lifting cylinder, the push rod end of the third lifting cylinder is fixedly connected with the third sucker, and the third sucker is communicated with a vacuum source; the third conveying mechanism drives the third sucker to move so as to suck the workpiece on the third conveyor belt onto the swing disc seat; and the second conveying mechanism drives the second sucker to move so as to suck the workpiece on the second conveying belt onto the third conveying belt.

Further, a first photoelectric switch is arranged at the conveying tail end of the second conveyor belt; and a second photoelectric switch is arranged at the conveying tail end of the third conveyor belt.

The beneficial effects of the utility model are as follows:

Compared with the prior art, the transverse cutting mechanism and the longitudinal cutting mechanism are arranged, so that the function of cutting the circuit board in two directions can be realized, the circuit board does not need to be disassembled again and rotated in the cutting process, the labor force of workers is further reduced, the production time is saved, the production efficiency of equipment is greatly improved, the large-scale production of enterprises is facilitated, and the practicability is high.

Drawings

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic structural view of the transverse cutting mechanism of the present utility model;

FIG. 3 is a schematic view of the slitting mechanism according to the present utility model;

FIG. 4 is a schematic view of a first conveying mechanism according to the present utility model;

FIG. 5 is a schematic view of a second conveying mechanism according to the present utility model;

FIG. 6 is a schematic structural view of a third conveying mechanism according to the present utility model;

FIG. 7 is a schematic view of a first stage frame according to the present utility model;

fig. 8 is a schematic structural view of a second stage frame according to the present utility model.

In the figure, 1, a first workbench; 2. a board separating device; 3. a first conveying mechanism; 4. a first conveyor belt; 5. a cutting mechanism; 6. an upper hob; 7. a lower hob; 8. a rotating mechanism; 9. a transverse cutting mechanism; 10. a slitting mechanism; 11. a first suction cup; 12. a feeding belt; 13. a first X-axis linear module; 14. a first lifting cylinder; 15. lifting columns; 16. a first stage frame; 17. a positioning pin; 18. a first hob groove; 19. a second stage frame; 20. a second hob groove; 21. a servo motor; 22. a gear structure; 23. a second conveyor belt; 24. a second conveying mechanism; 25. a second X-axis linear module; 26. a second lifting cylinder; 27. a second suction cup; 28. a second work table; 29. a wobble plate device; 30. a third conveying mechanism; 31. a third conveyor belt; 32. a swinging disc seat; 33. an XYZ axis straight line module; 34. a third lifting cylinder; 35. a third suction cup; 36. a first photoelectric switch; 37. and a second photoelectric switch.

Detailed Description

The following is a further description of embodiments of the utility model, taken in conjunction with the accompanying drawings:

As shown in fig. 1-8, a bidirectional automatic board dividing machine comprises a first workbench 1 and a board dividing device 2; the plate separating device 2 is arranged on the first workbench 1, the plate separating device 2 comprises a first conveying mechanism 3, a first conveying belt 4 and a cutting mechanism 5, an upper hob 6 and a lower hob 7 are arranged on the cutting mechanism 5, the upper hob 6 and the lower hob 7 are oppositely arranged and are in transmission connection with each other, and a rotating mechanism 8 for driving the lower hob 7 to rotate is arranged on the cutting mechanism 5; the cutting mechanism 5 is divided into a transverse cutting mechanism 9 and a longitudinal cutting mechanism 10, and the transverse cutting mechanism 9 is also connected with a driving mechanism for driving the upper hob 6 and the lower hob 7 to move back and forth;

The first conveyor belt 4 is positioned between the transverse cutting mechanism 9 and the longitudinal cutting mechanism 10, a first sucker 11 is arranged at the moving end of the first conveying mechanism 3, the first conveying mechanism 3 drives the first sucker 11 to move so as to suck the workpiece on the feeding belt 12 into the transverse cutting mechanism 9 for transverse cutting processing, and drives the first sucker 11 to move so as to suck the workpiece which is subjected to transverse cutting processing in the transverse cutting mechanism 9 onto the first conveyor belt 4; the first conveyor belt 4 is used for conveying the workpiece to the slitting mechanism 10 for slitting;

In this embodiment, it should be noted that the main problems in the prior art are: the traditional board dividing machine can only cut one direction of the circuit board, for example, when the transverse direction of the circuit board is cut, the circuit board needs to be disassembled and rotated to be positioned, and then the cutting in the longitudinal direction of the circuit board is carried out, but the process not only needs to consume more labor force, but also has lower production efficiency when the two directions of the circuit board need to be cut, and is not beneficial to enterprises to carry out large-scale production;

Therefore, after the improvement of the application, the function of cutting the circuit board in two directions can be realized by arranging the transverse cutting mechanism 9 and the longitudinal cutting mechanism 10, and the circuit board does not need to be disassembled again and rotated in the cutting process, so that the labor force of workers is reduced, the production time is saved, the production efficiency of equipment is greatly improved, the large-scale production of enterprises is facilitated, and the practicability is strong.

As shown in fig. 1 and 4, as a preferred embodiment; the first conveying mechanism 3 further comprises a first X-axis linear module 13 and a first lifting cylinder 14, the first X-axis linear module 13 is fixedly connected to the first workbench 1, the moving end of the first X-axis linear module 13 is fixedly connected with the first lifting cylinder 14, the push rod end of the first lifting cylinder 14 is connected with a lifting column 15, the other end of the lifting column 15 is fixedly connected with a first sucker 11, and the first sucker 11 is communicated with a vacuum source; it can be understood that the first X-axis linear module 13 can drive the first lifting cylinder 14 and the first suction cup 11 to move left and right, so that the workpiece is sucked onto the transverse cutting mechanism 9 on the feeding belt 12 for transverse cutting processing, and then sucked onto the first conveyor belt 4; the first lifting cylinder 14 can drive the first sucking disc 11 to move up and down, and then effectively suck the workpiece, and meanwhile, the quantity of the first sucking discs 11 is set according to the quantity of the transversely cut workpieces, so that all transversely cut workpieces can be transferred after transverse cutting, and the degree of automation is high.

As a preferred embodiment; the side surface of the cutting edge of the upper hob 6 is contacted with the side surface of the cutting edge of the lower hob 7 to realize the transmission of the upper hob 6 and the lower hob 7; it can be understood that when the lower hob 7 rotates, a larger friction force can be generated, and the upper hob 6 is driven to rotate, so that two sets of rotating mechanisms 8 are not needed in the process, and energy consumption can be saved.

As shown in fig. 1, 2, 7, as a preferred embodiment; the transverse cutting mechanism 9 is further provided with a first objective table frame 16, the first objective table frame 16 is fixedly connected to the first workbench 1, the first objective table frame 16 is located between the upper hob 6 and the lower hob 7 of the transverse cutting mechanism 9, the first objective table frame 16 is provided with a positioning pin 17 for positioning an inserted workpiece, and the first objective table frame 16 is further provided with a first hob groove 18 penetrating through the upper hob 6 and the lower hob 7 of the transverse cutting mechanism 9, so that the top surface and the bottom surface of the workpiece are respectively contacted with the upper hob 6 and the lower hob 7 of the transverse cutting mechanism 9 to realize cutting; the first objective table frame 16 is further provided with a placing groove, a workpiece can be placed, and in the transverse cutting process, the upper hob 6 and the lower hob 7 effectively cut the workpiece through the first hob groove 18, so that the structure is simple, and the efficiency is high.

As shown in fig. 1, 3, 8, as a preferred embodiment; the longitudinal cutting mechanism 10 is further provided with a second objective table frame 19, the second objective table frame 19 is fixedly connected to the first workbench 1, the second objective table frame 19 is located between the upper hob 6 and the lower hob 7 of the longitudinal cutting mechanism 10, the second objective table frame 19 is further provided with a second hob groove 20 penetrating through the upper hob 6 and the lower hob 7 of the longitudinal cutting mechanism 10, and the top surface and the bottom surface of a workpiece are respectively contacted with the upper hob 6 and the lower hob 7 of the longitudinal cutting mechanism 10 to realize cutting; the second objective table frame 19 is divided into two support bodies, the work piece passes through the two support bodies, and the second hob grooves 20 are formed in the two support bodies, so that under the drive of the first conveyor belt 4, the upper hob 6 and the lower hob 7 can effectively cut the work piece through the second hob grooves 20, and the work efficiency is high.

As shown in fig. 1, 2, 3, as a preferred embodiment; the rotating mechanism 8 comprises a servo motor 21 and a gear structure 22; the servo motor 21 is arranged on the first workbench 1, the servo motor 21 is in transmission connection with the gear structure 22, and the rotating end of the gear structure 22 is fixedly connected with the lower hob 7; the rotating mechanism 8 adopts gear transmission, so that the effect of accurate rotation can be achieved, the energy consumption is low, and the cost is saved; in addition, a plurality of rotating mechanisms 8 can be arranged on the upper hob 6, so that the upper hob 6 does not need to be rotated by the lower hob 7, the cutting strength can be enhanced, and workpieces with higher hardness can be cut, thereby expanding the application range of the plate separator.

As shown in fig. 1 and 5, as a preferred embodiment; the plate separating device 2 further comprises a second conveying belt 23 and a second conveying mechanism 24, wherein the second conveying belt 23 and the second conveying mechanism 24 are positioned at the rear side of the slitting mechanism 10, and the second conveying belt 23 is used for receiving workpieces subjected to slitting processing by the slitting mechanism 10; the second conveying mechanism 24 comprises a second X-axis linear module 25, a second lifting cylinder 26 and a second sucking disc 27, the second X-axis linear module 25 is fixedly connected to the first workbench 1, the moving end of the second X-axis linear module 25 is fixedly connected with the second lifting cylinder 26, the push rod end of the second lifting cylinder 26 is fixedly connected with the second sucking disc 27, and the second sucking disc 27 is communicated with a vacuum source; the second conveyor belt 23 is mainly used for receiving the workpiece after being slit, and transferring the workpiece to the third conveyor belt 31 through the second conveying mechanism 24; meanwhile, the second suction cups 27 are separately connected with the second lifting cylinders 26, that is, one second lifting cylinder 26 is connected with a group of second suction cups 27 (one group may be one or more), the purpose of the design is to prevent the suction interference, and when one second lifting cylinder 26 drives the second suction cups 27 to suck the workpiece, the other second lifting cylinder may not drive the workpiece.

As shown in fig. 1 and 6, as a preferred embodiment; the board separator further comprises a second table 28 and a wobble plate device 29; the swinging disc device 29 is mounted on the second workbench 28, the swinging disc device 29 comprises a third conveying mechanism 30, a third conveying belt 31 and a swinging disc seat 32, the third conveying belt 31 and the swinging disc seat 32 are respectively arranged on the second workbench 28, the third conveying mechanism 30 comprises an XYZ-axis linear module 33, a third lifting cylinder 34 and a third sucking disc 35, the XYZ-axis linear module 33 is fixedly connected to the second workbench 28, the moving end of the XYZ-axis linear module 33 is fixedly connected with the third lifting cylinder 34, the push rod end of the third lifting cylinder 34 is fixedly connected with the third sucking disc 35, and the third sucking disc 35 is communicated with a vacuum source; the third conveying mechanism 30 drives the third sucker 35 to move so as to suck the workpiece on the third conveyor belt 31 onto the swing disc seat 32; the second conveying mechanism 24 drives the second sucking discs 27 to move so as to suck the workpieces on the second conveyor belt 23 onto the third conveyor belt 31; by arranging the swaying disc device 29, the cut workpiece can be driven to be placed on the swaying disc seat 32 through the third conveying mechanism 30, so that automatic discharging is realized; the third lifting cylinder 34 and the third sucker 35 are also connected independently, so that interference is prevented; furthermore, the pallet base 32 has two holding pockets, one for stacking empty pallets and one for holding workpieces, the transfer of the empty pallets being possible by the third conveyor 30.

As shown in fig. 1, as a preferred embodiment; the conveying tail end of the second conveyor belt 23 is provided with a first photoelectric switch 36; the conveying tail end of the third conveyor belt 31 is provided with a second photoelectric switch 37; by providing the first and second photoelectric switches 36 and 37 (for detecting whether the workpiece is in place), signals can be transmitted to the controller after the workpiece is in place, and the corresponding second and third conveying mechanisms 24 and 30 are started to operate by the controller.

The working principle of the utility model is as follows: the workpiece is firstly sucked into the transverse cutting mechanism 9 through the first conveying mechanism 3 for cutting, then the workpiece is continuously sucked onto the first conveying mechanism 3, the workpiece is driven onto the longitudinal cutting mechanism 10 through the first conveying mechanism 4 for cutting, then the workpiece is directly conveyed onto the second conveying belt 23, at the moment, the workpiece can be sucked and transferred onto the third conveying belt 31 through the second conveying mechanism 24, and finally the workpiece is sucked and conveyed into an empty disc on the disc swinging seat 32 through the third conveying mechanism 30.

The above embodiments are merely illustrative of the preferred embodiments of the present utility model and are not intended to limit the scope of the present utility model, and various modifications and improvements made by those skilled in the art to the technical solution of the present utility model should fall within the scope of protection defined by the claims of the present utility model without departing from the spirit of the design of the present utility model.

Claims

1. A two-way automatic board separator which characterized in that:

Comprises a first workbench and a plate separating device; the plate separating device is arranged on the first workbench and comprises a first conveying mechanism, a first conveying belt and a cutting mechanism, an upper hob and a lower hob are arranged on the cutting mechanism, the upper hob and the lower hob are oppositely arranged and are in transmission connection, and a rotating mechanism for driving the lower hob to rotate is arranged on the cutting mechanism; the cutting mechanism is divided into a transverse cutting mechanism and a longitudinal cutting mechanism, and the transverse cutting mechanism is also connected with a driving mechanism for driving the upper hob and the lower hob to move back and forth;

2. A bi-directional automatic board separator as in claim 1 wherein: the first conveying mechanism further comprises a first X-axis linear module and a first lifting cylinder, the first X-axis linear module is fixedly connected to the first workbench, the moving end of the first X-axis linear module is fixedly connected with the first lifting cylinder, the push rod end of the first lifting cylinder is connected with a lifting column, the other end of the lifting column is fixedly connected with a first sucker, and the first sucker is communicated with a vacuum source.

3. A bi-directional automatic board separator as claimed in claim 2, wherein: the side surface of the upper hob blade is contacted with the side surface of the lower hob blade to realize the transmission of the upper hob and the lower hob.

4. A bi-directional automatic board separator as claimed in claim 3, wherein: the automatic cutting machine is characterized in that a first objective table frame is further arranged on the transverse cutting mechanism and fixedly connected to a first workbench, the first objective table frame is located between the upper hob and the lower hob of the transverse cutting mechanism, a positioning pin is arranged on the first objective table frame and used for positioning and inserting workpieces, and a first hob groove penetrating through the upper hob and the lower hob of the transverse cutting mechanism is further formed in the first objective table frame, so that the top surface and the bottom surface of the workpieces are respectively contacted with the upper hob and the lower hob of the transverse cutting mechanism to realize cutting.

5. A bi-directional automatic board separator as in claim 4 wherein: the vertical cutting mechanism is further provided with a second objective table frame, the second objective table frame is fixedly connected to the first workbench, the second objective table frame is located between the upper hob and the lower hob of the vertical cutting mechanism, and the second objective table frame is further provided with a second hob groove penetrating through the upper hob and the lower hob of the vertical cutting mechanism, so that the top surface and the bottom surface of a workpiece are in contact with the upper hob and the lower hob of the vertical cutting mechanism respectively to realize cutting.

6. A bi-directional automatic board separator as in claim 5 wherein: the rotating mechanism comprises a servo motor and a gear structure; the servo motor is arranged on the first workbench and is in transmission connection with the gear structure, and the rotating end of the gear structure is fixedly connected with the lower hob.

7. A bi-directional automatic board separator as in claim 6 wherein: the plate separating device further comprises a second conveying belt and a second conveying mechanism, wherein the second conveying belt and the second conveying mechanism are both positioned at the rear side of the slitting mechanism, and the second conveying belt is used for receiving the workpiece slit by the slitting mechanism; the second conveying mechanism comprises a second X-axis linear module, a second lifting cylinder and a second sucker, wherein the second X-axis linear module is fixedly connected to the first workbench, the moving end of the second X-axis linear module is fixedly connected with the second lifting cylinder, the push rod end of the second lifting cylinder is fixedly connected with the second sucker, and the second sucker is communicated with the vacuum source.

8. A bi-directional automatic board separator as in claim 7 wherein: the plate separating machine further comprises a second workbench and a swinging plate device; the swinging disc device is arranged on the second workbench and comprises a third conveying mechanism, a third conveying belt and a swinging disc seat, wherein the third conveying belt and the swinging disc seat are respectively arranged on the second workbench, the third conveying mechanism comprises an XYZ-axis linear module, a third lifting cylinder and a third sucker, the XYZ-axis linear module is fixedly connected to the second workbench, the moving end of the XYZ-axis linear module is fixedly connected with the third lifting cylinder, the push rod end of the third lifting cylinder is fixedly connected with the third sucker, and the third sucker is communicated with a vacuum source; the third conveying mechanism drives the third sucker to move so as to suck the workpiece on the third conveyor belt onto the swing disc seat; and the second conveying mechanism drives the second sucker to move so as to suck the workpiece on the second conveying belt onto the third conveying belt.

9. A bi-directional automatic board separator as in claim 8 wherein: a first photoelectric switch is arranged at the conveying tail end of the second conveyor belt; and a second photoelectric switch is arranged at the conveying tail end of the third conveyor belt.