CN111230033A

CN111230033A - Automatic assembly system for chain cutter

Info

Publication number: CN111230033A
Application number: CN202010058794.2A
Authority: CN
Inventors: 王泉福; 马国章
Original assignee: Wuhu Jingfeng Excelsior & Sharp Garden Machinery Technology Co ltd
Current assignee: Wuhu Jingfeng Excelsior & Sharp Garden Machinery Technology Co ltd
Priority date: 2020-01-19
Filing date: 2020-01-19
Publication date: 2020-06-05
Anticipated expiration: 2040-01-19
Also published as: CN111230033B

Abstract

The invention discloses an automatic assembly system of chain cutters, which comprises: assembly station, first material feeding unit, second material feeding unit, third material feeding unit and riveting set, wherein: the assembling table comprises an upper platform and a lower platform which are arranged up and down and a channel is reserved between the upper platform and the lower platform, and the upper platform is provided with a through groove and a first guide groove; the lower platform is provided with a second guide chute and a limiting part; the first feeding device comprises a conveying belt with one end penetrating through the channel and a first driving mechanism for driving the conveying belt to move; the second feeding device comprises a first conveying channel and a first conveyor belt, and the first conveyor belt and the bottom of the first guide chute are positioned in the same plane; the third feeding device comprises a second conveying channel and a second conveyor belt, and the second conveyor belt and the bottom of the second guide chute are positioned in the same plane; the riveting device comprises a riveting head positioned above the through groove and a driving mechanism used for driving the riveting head to move up and down. The automatic assembling equipment can effectively improve the working efficiency.

Description

Automatic assembly system for chain cutter

Technical Field

The invention relates to the technical field of chain cutter processing, in particular to an automatic assembly system for a chain cutter.

Background

The chain knife is mainly formed by a plurality of blades and two connecting pieces which are arranged between two adjacent blades up and down and are connected with the blades through a riveting process. The existing riveting equipment is formed by combining a plurality of processing stations, and has a complex structure and low efficiency.

Disclosure of Invention

Based on the technical problems in the background art, the invention provides an automatic assembly system for chain cutters.

The invention provides an automatic assembly system of chain cutters, which comprises: the assembly station, be used for carrying the first material feeding unit of blade, be used for carrying the second material feeding unit and the third material feeding unit of connection piece and be used for riveted riveting set, wherein:

the assembling table comprises an upper platform and a lower platform, the upper platform and the lower platform are arranged up and down, a channel is reserved between the upper platform and the lower platform, the upper platform is provided with a through groove which is communicated with the channel and can be used for an upper connecting sheet to pass through, and a first guide groove which is positioned on one side of the through groove and is communicated with the through groove; a second guide groove parallel to the first guide groove and a limiting part which is positioned at one end of the second guide groove and is positioned in the same vertical plane with the inner wall of the through groove at the side far away from the first guide groove are arranged at one side of the lower platform close to the upper platform;

the first feeding device comprises a conveying belt and a first driving mechanism for driving the conveying belt to move, one end of the conveying belt penetrates through the channel to extend to the other side of the channel, and the conveying belt comprises a first conveying belt positioned on one side, close to the first guide chute, of the through groove and a second conveying belt positioned on one side, far away from the first guide chute, of the through groove;

the second feeding device comprises a first conveying channel for a single connecting sheet to pass through and a first conveying belt arranged at the bottom of the first conveying channel, the output end of the first conveying channel is in butt joint with one end, far away from the through groove, of the first guide chute, and the first conveying belt and the chute bottom of the first guide chute are located in the same plane;

the third feeding device comprises a second conveying channel for a single connecting sheet to pass through and a second conveyor belt arranged at the bottom of the second conveying channel, the output end of the second conveying channel is butted with one end, away from the limiting part, of the second guide chute, and the second conveyor belt and the groove bottom of the second guide chute are positioned in the same plane;

the riveting device comprises a riveting head positioned above the through groove and a driving mechanism used for driving the riveting head to move up and down.

Preferably, the limiting part is close to one side of the second guide chute and is positioned below the through groove, a movable block capable of moving up and down is arranged below the through groove, and the movable block is positioned between the first conveying belt and the second conveying belt.

Preferably, the movable block is arranged on the lower platform, the cylinder is arranged below the lower platform, and a piston rod of the cylinder penetrates through the lower platform to be connected with the movable block so as to drive the movable block to move up and down.

Preferably, the inner side of the through groove is provided with a rubber sheet circumferentially arranged along the inner wall thereof, and the upper surface of the rubber sheet and the groove bottom of the first material guide groove are positioned in the same plane.

Preferably, the rubber sheet is provided with a plurality of cuts arranged at intervals in the circumferential direction thereof.

Preferably, the lower platform is provided with a groove which is coaxial with the rivet head and is positioned below the rivet head.

Preferably, the first conveying belt is provided with a plurality of first positioning grooves arranged in parallel along the moving direction of the first conveying belt, the first conveying belt is provided with a plurality of second positioning grooves arranged in parallel along the moving direction of the first conveying belt, and each first positioning groove corresponds to each second positioning groove in a one-to-one manner.

Preferably, the first conveying belt is provided with first positioning blocks, and the first positioning blocks are arranged at intervals along the moving direction of the first conveying belt to form first positioning grooves in the first conveying belt; the second conveying belt is provided with second positioning blocks, and the second positioning blocks are arranged at intervals along the moving direction of the second conveying belt to form second positioning grooves in the second conveying belt.

According to the invention, the assembly table is set to be of an upper platform and a lower platform, a channel is arranged between the upper platform and the lower platform, the upper platform is provided with a through groove and a first guide groove, the lower platform is provided with a second guide groove and a limiting part, and a conveying belt in a first feeding device for conveying a blade passes through the channel, so that the blade conveyed by the first feeding device passes through the lower part of the riveting head; meanwhile, a first conveying channel in a second feeding device for conveying the connecting sheets is in butt joint with one end, away from the through groove, of the first guide groove, a second conveying channel in a third feeding device for conveying the connecting sheets is in butt joint with one end, away from the limiting part, of the second guide groove, the second feeding device and the third feeding device are matched to convey the connecting sheets to the riveting head, the connecting sheets conveyed by the second feeding device and the third feeding device are located on the upper side and the lower side of the blade respectively, and the riveting device can rivet the connecting sheets together through one-time action and can realize continuous riveting work along with the movement of each feeding device. The automatic assembly equipment can effectively improve the working efficiency, needs few power parts and can effectively save energy consumption.

Drawings

FIG. 1 is a schematic structural diagram of an automatic assembly system for chain cutters according to the present invention;

fig. 2 is a schematic view of the working state of the automatic assembly system for chain cutters according to the present invention.

Detailed Description

The technical solution of the present invention will be described in detail below with reference to specific examples.

As shown in fig. 1-2, fig. 1 is a schematic structural diagram of an automatic assembly system for chain cutters in accordance with the present invention; fig. 2 is a schematic view of the working state of the automatic assembly system for chain cutters according to the present invention.

Referring to fig. 1-2, the invention provides an automatic assembly system for chain cutters, comprising: the assembly station, be used for carrying the first material feeding unit of blade, be used for carrying the second material feeding unit 2 and the third material feeding unit 3 of connection piece and be used for riveted riveting set, wherein:

the assembly table comprises an upper platform 4 and a lower platform 5, the upper platform 4 and the lower platform 5 are arranged up and down, a channel is reserved between the upper platform 4 and the lower platform 5, the upper platform 4 is provided with a through groove a communicated with the channel and allowing an upper connecting sheet to pass through, and a first guide chute b located on one side of the through groove a and communicated with the through groove a, so that a workpiece moving in the direction of the first guide chute b is blocked by the side wall of the through groove a away from one side of the first guide chute b. A second material guide groove d parallel to the first material guide groove b and a limiting part e which is positioned at one end of the second material guide groove d and is positioned in the same vertical plane with the inner wall of the through groove a at the side far away from the first material guide groove b are arranged at one side of the lower platform 5 close to the upper platform 4, so that the limiting part e is used for blocking the workpiece moving from the direction of the second material guide groove d. The first feeding device comprises a conveying belt 1 and a first driving mechanism used for driving the conveying belt 1 to move, one end of the conveying belt 1 penetrates through the channel to extend to the other side of the channel, and the conveying belt 1 comprises a first conveying belt located on one side, close to the first guide chute b, of the through groove a and a second conveying belt located on one side, far away from the first guide chute b, of the through groove a. The second feeding device 2 comprises a first conveying channel for a single connecting sheet to pass through and a first conveying belt arranged at the bottom of the first conveying channel, the output end of the first conveying channel is in butt joint with one end, far away from the through groove a, of the first guide chute b, and the first conveying belt and the groove bottom of the first guide chute b are located on the same plane. The third feeding device 3 comprises a second conveying channel for a single connecting sheet to pass through and a second conveyor belt arranged at the bottom of the second conveying channel, the output end of the second conveying channel is in butt joint with one end, away from the limiting part e, of the second guide chute d, and the second conveyor belt and the groove bottom of the second guide chute d are located in the same plane. The riveting device comprises a riveting head 6 positioned above the through groove a and a driving mechanism for driving the riveting head 6 to move up and down.

According to the invention, the assembly table is set to be the structure of the upper platform 4 and the lower platform 5, the channel is arranged between the upper platform 4 and the lower platform 5, the through groove a and the first material guide groove b are arranged on the upper platform 4, the second material guide groove d and the limiting part e are arranged on the lower platform 5, and the conveying belt 1 in the first feeding device for conveying the blade passes through the channel, so that the blade conveyed by the first feeding device passes through the lower part of the riveting head 6; meanwhile, a first conveying channel in a second feeding device 2 used for conveying connecting pieces is in butt joint with one end, away from the through groove a, of the first guide groove b, a second conveying channel in a third feeding device 3 used for conveying the connecting pieces is in butt joint with one end, away from the limiting part e, of the second guide groove d, so that the connecting pieces are conveyed to the riveting head 6 by matching of the second feeding device and the third feeding device, the connecting pieces conveyed by the second feeding device and the third feeding device are located on the upper side and the lower side of the blade respectively, the riveting device can rivet the connecting pieces in a riveting mode through one-step action, and continuous riveting work can be achieved along with movement of the feeding devices. The automatic assembly equipment can effectively improve the working efficiency, needs few power parts and can effectively save energy consumption.

In addition, in this embodiment, the limiting portion e is close to one side of the second material guiding groove d and is located below the through groove a, and the movable block 7 capable of moving up and down is located below the through groove a, and the movable block 7 is located between the first conveying belt and the second conveying belt, so as to ensure that the connecting sheet below the blade is attached to the connecting sheet, and further enhance the riveting effect.

Preferably, the movable block 7 is installed on the lower platform 5, the cylinder is installed below the lower platform 5, and a piston rod of the cylinder penetrates through the lower platform 5 and is connected with the movable block 7 to drive the movable block 7 to move up and down, so that the movable block 7 is pulled to descend during loading, the upper surface of the movable block 7 and the groove bottom of the second material guide groove d are located in the same plane, a connecting piece in the second material guide groove d smoothly enters the movable block 7, and the movable block 7 is pushed to move up during riveting, so that the back aje piece on the movable block 7 is attached to the blade.

In this embodiment, a groove coaxial with the rivet joint 6 is provided on the lower platform 5 and below the rivet joint 6 to ensure smooth riveting operation.

In this embodiment, the inner side of the through groove a is provided with a rubber sheet c circumferentially arranged along the inner wall thereof, and the upper surface of the rubber sheet c and the groove bottom of the first material guide groove b are located in the same plane, so as to ensure that the connecting sheet smoothly translates to the inner side of the through groove a.

In this embodiment, the rubber sheet c is provided with a plurality of notches arranged at intervals along the circumferential direction thereof, so as to ensure that the connecting sheet strung on the rubber sheet c can smoothly pass through the rubber sheet c along with the downward movement of the rivet joint 6 to be attached to the blade.

In this embodiment, the first conveying belt is provided with a plurality of first positioning grooves arranged in parallel along the moving direction of the first conveying belt, the first conveying belt is provided with a plurality of second positioning grooves arranged in parallel along the moving direction of the first conveying belt, and each first positioning groove corresponds to each second positioning groove in a one-to-one manner. So as to ensure the stability of the relative arrangement of the blades in the conveying process.

In this embodiment, the first conveyor belt is provided with first positioning blocks 8, and the first positioning blocks 8 are arranged at intervals along the moving direction of the first conveyor belt to form first positioning grooves therebetween; the second conveying belt is provided with second positioning blocks 9, and the second positioning blocks 9 are arranged at intervals along the moving direction of the second conveying belt to form second positioning grooves in the second conveying belt.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. An automatic chain cutter assembling system, comprising: the assembly station, be used for carrying the first material feeding unit of blade, be used for carrying second material feeding unit (2) and third material feeding unit (3) of connection piece and be used for riveted riveting set, wherein:

the assembling platform comprises an upper platform (4) and a lower platform (5), the upper platform (4) and the lower platform (5) are arranged up and down, a channel is reserved between the upper platform and the lower platform, a through groove (a) which is communicated with the channel and can be used for an upper connecting sheet to pass through and a first guide groove (b) which is positioned on one side of the through groove (a) and is communicated with the through groove (a) are arranged on the upper platform (4); a second material guide groove (d) parallel to the first material guide groove (b) and a limiting part (e) which is positioned at one end of the second material guide groove (d) and is positioned in the same vertical plane with the inner wall of the through groove (a) at one side far away from the first material guide groove (b) are arranged at one side, close to the upper platform (4), of the lower platform (5);

the first feeding device comprises a conveying belt (1) and a first driving mechanism for driving the conveying belt (1) to move, one end of the conveying belt (1) penetrates through the channel to extend to the other side of the channel, and the conveying belt (1) comprises a first conveying belt positioned on one side, close to the first guide chute (b), of the through groove (a) and a second conveying belt positioned on one side, far away from the first guide chute (b), of the through groove (a);

the second feeding device (2) comprises a first conveying channel for a single connecting sheet to pass through and a first conveying belt arranged at the bottom of the first conveying channel, the output end of the first conveying channel is in butt joint with one end, far away from the through groove (a), of the first guide chute (b), and the first conveying belt and the bottom of the first guide chute (b) are located in the same plane;

the third feeding device (3) comprises a second conveying channel for a single connecting sheet to pass through and a second conveyor belt arranged at the bottom of the second conveying channel, the output end of the second conveying channel is butted with one end, away from the limiting part (e), of the second guide chute (d), and the second conveyor belt and the bottom of the second guide chute (d) are located in the same plane;

the riveting device comprises a riveting head (6) positioned above the through groove (a) and a driving mechanism used for driving the riveting head (6) to move up and down.

2. The automatic assembly system of claim 1, wherein the limiting portion (e) is located near one side of the second material guiding groove (d) and below the through groove (a) and is provided with a movable block (7) capable of moving up and down, and the movable block (7) is located between the first conveying belt and the second conveying belt.

3. The automatic assembly system of the chain cutter as claimed in claim 2, wherein the movable block (7) is mounted on the lower platform (5), the cylinder is mounted below the lower platform (5), and a piston rod of the cylinder penetrates through the lower platform (5) and is connected with the movable block (7) to drive the movable block (7) to move up and down.

4. The automatic assembling system of chain cutters as set forth in claim 1, wherein the through groove (a) is provided inside with a rubber sheet (c) circumferentially disposed along an inner wall thereof, and an upper surface of the rubber sheet (c) is located in the same plane as a groove bottom of the first guide chute (b).

5. The automatic assembling system for chain cutters as set forth in claim 4, wherein the rubber sheet (c) is provided with a plurality of notches arranged at intervals in a circumferential direction thereof.

6. The automatic assembly system of chain cutters as claimed in claim 1, wherein the lower platform (5) is provided with a groove coaxial with the rivet head (6) below the rivet head (6).

7. The automatic assembling system for chain cutters as set forth in any one of claims 1 to 6, wherein the first conveyor belt is provided with a plurality of first positioning grooves arranged side by side in the moving direction thereof, the first conveyor belt is provided with a plurality of second positioning grooves arranged side by side in the moving direction thereof, and each first positioning groove corresponds to each second positioning groove.

8. The automatic assembling system of chain cutter according to claim 7, characterized in that the first conveyor belt is provided with first positioning blocks (8), and each first positioning block (8) is arranged at intervals along the moving direction of the first conveyor belt to form a first positioning groove; the second conveying belt is provided with second positioning blocks (9), and the second positioning blocks (9) are arranged at intervals along the moving direction of the second conveying belt to form second positioning grooves in the second conveying belt.