CN211028908U - Automatic door curtain assembling and buckling production line - Google Patents

Abstract

The utility model discloses an automatic dress of door curtain is detained production line, include: transfer chain, magnetism detain assembly device, transfer passage, pusher, loading attachment and press and detain the device, wherein: a pressing and buckling station platform is arranged on one side of the conveying line; the magnetic buckle assembling device comprises a material loading platform, a feeding mechanism, a propelling mechanism, a pressing mechanism and a power mechanism. The utility model discloses utilize transfer chain, magnetism to detain assembly device, transfer passage, pusher, loading attachment and press mutually supporting between the knot device to realize inhaling the pipelined mode of production of magnetic door curtain, can effectively improve machining efficiency.

Description

Automatic door curtain assembling and buckling production line

Technical Field

The utility model relates to a processing equipment technical field especially relates to an automatic dress of door curtain detains production line.

Background

The door curtain is a common object used by people at entrances and exits of families, markets, units and the like, is attractive in appearance and can prevent mosquitoes from entering, and can be used for indoor heat preservation in winter. In order to be convenient to open/close, the opening of the existing door curtain is provided with the magnetic buckle, so that the opposite door curtain can be automatically attracted by utilizing the attraction capacity of the magnetic buckle.

SUMMERY OF THE UTILITY MODEL

Based on the technical problem who exists among the above-mentioned background art, the utility model provides an automatic dress of door curtain detains production line.

The utility model provides an automatic dress of door curtain detains production line, include: transfer chain, magnetism detain assembly device, transfer passage, pusher, loading attachment and press and detain the device, wherein:

a pressing and buckling station table is arranged on one side of the conveying direction of the conveying line;

the magnetic buckle assembling device comprises a material loading platform, a feeding mechanism, a propelling mechanism, a pressing mechanism and a power mechanism; the material carrying platform is connected with the power mechanism and is driven by the power mechanism to do linear reciprocating motion, an assembling station platform is arranged on one side of the material carrying platform in the motion direction, a plurality of material storage grooves used for storing workpieces A are arranged on the material carrying platform, the material storage grooves are arranged in parallel along the motion direction, and one ends of the material storage grooves close to the assembling station platform are all opened to form discharge ports; the feeding mechanism is used for conveying the workpiece B to the assembling station table; the pushing mechanism is used for pushing the workpiece A in the storage groove to the upper part of the assembling station table; the pressing mechanism is positioned above the assembling station table and used for pressing the workpiece A on the assembling station table into the workpiece B to form an assembly;

one end of the conveying channel is in butt joint with the assembling station platform, and the other end of the conveying channel is in butt joint with the pressing and buckling station platform;

the pushing device is used for pushing the assembly on the assembling station platform into the conveying channel and pushing the assembly to the pressing and buckling station platform through the conveying channel;

the conveying line is used for conveying the workpiece C to the pressing and buckling station table;

the feeding device is used for conveying the workpiece D to the pressing and buckling station table;

the pressing and buckling device is positioned at the pressing and buckling station table and is used for pressing and buckling the workpiece C and the workpiece D on the pressing and buckling station table with the assembly.

Preferably, the feeding mechanism comprises a vibrating disk a, a feeding channel and a pushing assembly, wherein: the pushing assembly is positioned on one side of the assembling station platform and comprises a pushing block and a power unit C for driving the pushing block to perform linear reciprocating motion towards the assembling work platform; one end of the feeding channel is in butt joint with a discharge hole of the vibrating disc A, and the other end of the feeding channel is located between the material pushing block and the assembling station table.

Preferably, the feeding mechanism is positioned on one side of the assembling station platform far away from the material loading platform.

Preferably, the feeding channel is located between the pushing assembly and the assembling workbench, and the extending direction of the feeding channel is parallel to the moving direction of the loading platform.

Preferably, the propelling mechanism comprises a magnetic propelling block and a power unit A connected with the propelling block, the propelling block is positioned on one side of each material storage groove close to the material outlet of the material storage groove and is driven by the power unit A to perform linear reciprocating motion along the motion direction of the material carrying table; the assembling station platform is positioned at one end of the motion direction of the propelling block.

Preferably, the propulsion block comprises a powerful magnet.

Preferably, the pressing mechanism comprises an upper pressing block and a power unit B, the upper pressing block is located above the assembling station table, the power unit B is used for driving the upper pressing block to reciprocate up and down, and the upper pressing block is made of ferromagnetic materials.

Preferably, the pushing device comprises a pushing block and a power unit D connected with the pushing block, wherein the pushing block is located on one side of the conveying channel, which is far away from the assembling station table, and is driven by the power unit D to perform linear reciprocating motion towards the direction of the conveying channel.

Preferably, the feeding device comprises a first feeding channel, a second feeding channel and a vibrating disk B, wherein: one end of the first feeding channel is provided with a feeding platform in butt joint with the first feeding channel, and one end of the first feeding channel, which is far away from the feeding platform, extends to the pressing and buckling station platform; the second feeding channel is positioned on one side of the extending direction of the first feeding channel and extends in the same direction as the first feeding channel, one end of the second feeding channel is in butt joint with the discharge hole of the vibrating disc B, and the other end of the second feeding channel is parallel to the conveying direction of the first feeding channel and is in butt joint with the feeding table; a first feeding push block and a power unit E for driving the first feeding push block to perform linear reciprocating motion towards the first feeding channel are arranged at one end, far away from the first feeding channel, of the feeding table; one side of the second feeding channel, which is far away from the feeding table, is provided with a second feeding push block arranged opposite to the feeding table and a power unit F for driving the second feeding push block to perform linear reciprocating motion towards the feeding table.

Preferably, the height of the end, butted with the pressing and buckling station table, of the conveying channel is lower than the height of the end, extending to the pressing and buckling station table, of the first feeding channel.

Preferably, the pressing and buckling device comprises an upper pressing and buckling plate and a first driving mechanism connected with the upper pressing and buckling plate, wherein the upper pressing and buckling plate is located above the pressing and buckling station platform and driven by the first driving mechanism to reciprocate up and down.

Preferably, the first driving mechanism is fixedly arranged on the pressing and buckling station table.

Preferably, the output end of the conveying line is provided with a blanking manipulator for transferring the material out of the conveying line.

Preferably, the conveying line comprises a first conveying line and a second conveying line which are arranged in parallel, the buckling station platform is positioned between the first conveying line and the second conveying line, a first buckling station is arranged on one side, close to the first conveying line, of the upper table top of the buckling station platform, and a second buckling station is arranged on one side, close to the second conveying line, of the upper table top of the buckling station platform; the two magnetic buckle assembling devices are respectively a first magnetic buckle assembling device and a second magnetic buckle assembling device, the first magnetic buckle assembling device is positioned on one side of the first conveying line far away from the second conveying line, and the second magnetic buckle assembling device is positioned on one side of the second conveying line far away from the first conveying line; the two conveying channels are respectively a first conveying channel and a second conveying channel, one end of the first conveying channel is in butt joint with an assembly station table in the first magnetic buckle assembly device, the other end of the first conveying channel is in butt joint with a first buckle pressing station in the buckle pressing station table, one end of the second conveying channel is in butt joint with an assembly station table in the second magnetic buckle assembly device, and the other end of the second conveying channel is in butt joint with a second buckle pressing station in the buckle pressing station table; the two pushing devices are respectively a first pushing device and a second pushing device, the first pushing device is used for pushing the assembly on the assembly station table in the first magnetic buckle assembling device into the first conveying channel and pushing the assembly to the first buckle pressing station through the first conveying channel, and the second pushing device is used for pushing the assembly on the assembly station table in the second magnetic buckle assembling device into the second conveying channel and pushing the assembly to the second buckle pressing station through the second conveying channel; the two feeding devices are respectively a first feeding device and a second feeding device, the first feeding device is used for conveying the workpiece D to the first buckling station, and the second feeding device is used for conveying the workpiece D to the second buckling station; the pressing and buckling device is used for pressing and buckling the workpiece C and the workpiece D on the first pressing and buckling station and the second pressing and buckling station with the assembly.

Preferably, the first conveying line comprises a first driving pulley, a first driven pulley and a first conveying belt for connecting the first driving pulley and the first driven pulley; the second conveying line comprises a second driving belt wheel, a second driven belt wheel and a second conveying belt for connecting the second driving belt wheel and the second driven belt wheel, and a driving shaft for connecting the second driving belt wheel and the first driving belt wheel is arranged between the second driving belt wheel and the first driving belt wheel; the first conveyor line or the second conveyor line further includes a second drive mechanism connected to the drive shaft for driving rotation of the drive shaft.

Preferably, a first synchronizing wheel and a second synchronizing wheel which are arranged along the conveying direction of the first conveying belt at intervals and a first synchronizing belt which connects the first synchronizing wheel and the second synchronizing wheel are arranged above the first conveying belt; a third synchronizing wheel and a fourth synchronizing wheel which are arranged along the conveying direction of the second conveying belt at intervals and a second synchronous belt for connecting the third synchronizing wheel and the fourth synchronizing wheel are arranged above the second conveying belt; a first rotating shaft fixedly connected with the first synchronizing wheel and the third synchronizing wheel is arranged between the first synchronizing wheel and the third synchronizing wheel, and a second rotating shaft fixedly connected with the second synchronizing wheel and the fourth synchronizing wheel is arranged between the second synchronizing wheel and the fourth synchronizing wheel; the first rotating shaft or the second rotating shaft is connected with the driving shaft through a transmission mechanism and rotates along with the rotation of the driving shaft.

Preferably, the transmission mechanism includes a fifth pulley fixedly mounted on the first rotating shaft or the second rotating shaft, a sixth pulley fixedly mounted on the driving shaft, and a third timing belt connecting the fifth pulley and the sixth pulley.

The utility model discloses in, through to the transfer chain, the equipment device is detained to magnetism, transfer passage, pusher, loading attachment sets up with the structure of pressing the knot device, make it inhale the door curtain when processing, usable magnetism is detained the lower cover that the equipment device was detained to magnetism and is assembled in order to form the sub-assembly with the magnetic path, utilize pusher and transfer passage cooperation to carry the sub-assembly of assembling to pressing and detain the station platform, utilize the transfer chain will inhale the continuous forward conveying of the banding gauze that the door curtain used, and make the side of the gauze that conveys pass through from the top that is located the sub-assembly of pressing the station bench, utilize loading attachment to detain used upper cover with magnetism and carry the pressing and detain the station platform, and make this upper cover be located the top of gauze, utilize the pressing the knot device to exert pressure to station bench side so that upper cover and sub-assembly pressfitting to the gauze. Therefore, the automatic pressing and buckling production line realizes the production line type production mode of the magnetic door curtain by utilizing the mutual matching among the conveying line, the magnetic buckle assembling device, the conveying channel, the pushing device, the feeding device and the pressing and buckling device, and can effectively improve the processing efficiency.

Drawings

Fig. 1 is a schematic structural view of an automatic door curtain fastening production line provided by the present invention;

fig. 2 is a side view of an automatic door curtain fastening production line provided by the present invention;

fig. 3 is a three-dimensional effect diagram of the conveying line in the automatic door curtain fastening production line provided by the utility model;

fig. 4 is a side view of the conveying line in the automatic door curtain fastening production line provided by the present invention;

fig. 5 is a schematic structural view of the magnetic buckle assembling device in the automatic door curtain buckle assembling line of the present invention;

fig. 6 is a three-dimensional effect diagram of the magnetic buckle assembling device in the automatic door curtain buckle assembling production line provided by the utility model;

fig. 7 is a schematic structural view of the feeding device in the automatic door curtain fastening production line provided by the present invention;

fig. 8 is a three-dimensional effect diagram of the feeding device in the automatic door curtain fastening production line provided by the utility model;

fig. 9 is a schematic structural view of the pressing device in an automatic door curtain fastening production line provided by the present invention;

fig. 10 is a three-dimensional effect diagram of the pressing buckle device in the automatic door curtain fastening production line provided by the utility model.

Detailed Description

The technical solution of the present invention will be described in detail by the following embodiments.

As shown in fig. 1-10, fig. 1 is a schematic structural view of an automatic fastening production line for a door curtain of the present invention; fig. 2 is a side view of an automatic door curtain fastening production line provided by the present invention; fig. 3 is a three-dimensional effect diagram of the conveying line in the automatic door curtain fastening production line provided by the utility model; fig. 4 is a side view of the conveying line in the automatic door curtain fastening production line provided by the present invention; fig. 5 is a schematic structural view of the magnetic buckle assembling device in the automatic door curtain buckle assembling line of the present invention; fig. 6 is a three-dimensional effect diagram of the magnetic buckle assembling device in the automatic door curtain buckle assembling production line provided by the utility model; fig. 7 is a schematic structural view of the feeding device in the automatic door curtain fastening production line provided by the present invention; fig. 8 is a three-dimensional effect diagram of the feeding device in the automatic door curtain fastening production line provided by the utility model; fig. 9 is a schematic structural view of the pressing device in an automatic door curtain fastening production line provided by the present invention; fig. 10 is a three-dimensional effect diagram of the pressing buckle device in the automatic door curtain fastening production line provided by the utility model.

Referring to fig. 1-2, the utility model provides an automatic dress of door curtain detains production line, include: transfer chain 1, magnetism detain assembly device, transfer passage 2, pusher 16, loading attachment and press and detain device 3, wherein:

and a pressing and buckling station table 4 is arranged on one side of the conveying direction of the conveying line 1. The magnetic buckle assembling device comprises a material loading table 5, a feeding mechanism 6, a propelling mechanism 7, a pressing mechanism 8 and a power mechanism 9; the material carrying platform 5 is connected with the power mechanism 9 and is driven by the power mechanism 9 to do linear reciprocating motion, an assembling station platform is arranged on one side of the material carrying platform 5 in the motion direction, a plurality of material storage grooves 501 used for storing workpieces A are arranged on the material carrying platform 5, the material storage grooves 501 are arranged in parallel along the motion direction, and one end of each material storage groove 501 close to the assembling station platform is opened to form a discharge hole; the feeding mechanism 6 is used for conveying the workpiece B to the assembling station table; the pushing mechanism 7 is used for pushing the workpiece a in the storage tank 501 to the upper part of the assembly station platform; a hold down mechanism 8 is located above the assembly station table for pressing the assembly station table workpiece a into the workpiece B to form an assembly. One end of the conveying channel 2 is in butt joint with the assembling station platform, and the other end of the conveying channel is in butt joint with the pressing and buckling station platform 4. The pushing device 16 is used for pushing the assembly on the assembling station platform into the conveying channel 2 and pushing the assembly to the pressing and buckling station platform 4 through the conveying channel 2, the pushing device 16 comprises a pushing block and a power unit D connected with the pushing block, the pushing block is located on one side, away from the assembling station platform, of the conveying channel 2, and the pushing block is driven by the power unit D to perform linear reciprocating motion towards the conveying channel 2. The conveying line 1 is used for conveying the workpiece C to the pressing and buckling station table 4. The feeding device is used for conveying the workpiece D to the pressing and buckling station table 4 and conveying the workpiece D to the upper side of the pressing and buckling station table 4. The pressing and buckling device 3 is located at the pressing and buckling station table 4 and used for pressing and buckling the workpiece C and the workpiece D on the pressing and buckling station table 4 and the assembly.

When the magnetic door curtain is processed, the magnetic blocks for processing the magnetic buttons are arranged in the material storage groove A in sequence in advance, the feeding mechanism 6 is utilized to convey the lower cover for processing the magnetic buttons to the assembly station table during work, the pushing mechanism 7 is utilized to push the magnetic blocks in the material storage groove 501 to the assembly station table, the magnetic blocks are positioned above the lower cover, and the pressing mechanism 8 is utilized to press the magnetic blocks on the assembly station table into the lower cover to form an assembly of the magnetic blocks and the lower cover; and then, the assembled combined part is conveyed to a pressing and buckling station table 4 by utilizing the matching of a pushing device 16 and a conveying channel 2, the belt-shaped gauze used for sucking the magnetic door curtain is continuously conveyed forwards by utilizing a conveying line 1, the side edge of the conveyed gauze passes through the upper part of the combined part positioned on the pressing and buckling station table 4, an upper cover used for magnetic buckling is conveyed to the pressing and buckling station table 4 by utilizing a feeding device and positioned above the gauze, and the upper cover and the combined part are pressed on the gauze by utilizing a pressing and buckling device 3, so that the upper cover and the combined part are pressed on the gauze, and the magnetic buckling work on the gauze is finished.

In addition, in order to realize automatic blanking, the present embodiment is also provided with a blanking manipulator 25 at the output end of the conveyor line 1 for transferring the material out of the conveyor line 1.

According to the above, the utility model discloses a to transfer chain 1, the assembly device is detained to magnetism, transfer passage 2, pusher 16, loading attachment sets up with the structure of pressing and detaining device 3, make it when processing and inhale the door curtain, usable magnetism is detained the assembly device and is assembled lower cover in the magnetism knot and magnetic path in order to form the sub-assembly, utilize pusher 16 and the cooperation of transfer passage 2 to carry the sub-assembly of assembling to pressing and detain station platform 4, utilize transfer chain 1 will inhale the continuous forward conveying of the banded greige that the door curtain used of magnetism, and make the side of the greige that conveys pass through from the top that is located the sub-assembly on pressing and detaining station platform 4, utilize loading attachment to carry the upper cover that the magnetism was detained and press and detain station platform 4, and make this upper cover be located the top of greige, utilize pressing and detain device 3 to exert pressure to station bench top so that upper cover and sub-assembly pressfitting are to the greige. Therefore, the automatic pressing and buckling production line realizes a production line type production mode of the magnetic door curtain by utilizing the mutual matching among the conveying line 1, the magnetic buckle assembling device, the conveying channel 2, the pushing device 16, the feeding device and the pressing and buckling device 3, and can effectively improve the processing efficiency.

Referring to fig. 3-4, the conveyor line 1 includes a first conveyor line 101 and a second conveyor line 102, the first conveyor line 101 and the second conveyor line 102 are arranged in parallel, the buckling station table 4 is located between the first conveyor line 101 and the second conveyor line 102, a first buckling station is arranged on one side, close to the first conveyor line 101, of the upper table surface of the buckling station table 4, and a second buckling station is arranged on one side, close to the second conveyor line 102, of the upper table surface of the buckling station table 4; the two magnetic buckle assembling devices are respectively a first magnetic buckle assembling device and a second magnetic buckle assembling device, the first magnetic buckle assembling device is positioned on one side of the first conveying line 101, which is far away from the second conveying line 102, and the second magnetic buckle assembling device is positioned on one side of the second conveying line 102, which is far away from the first conveying line 101; the two conveying channels 2 are respectively a first conveying channel and a second conveying channel, one end of the first conveying channel is in butt joint with an assembly station table in the first magnetic buckle assembly device, the other end of the first conveying channel is in butt joint with a first buckle pressing station in the buckle pressing station table 4, one end of the second conveying channel is in butt joint with an assembly station table in the second magnetic buckle assembly device, and the other end of the second conveying channel is in butt joint with a second buckle pressing station in the buckle pressing station table 4; the two pushing devices 16 are respectively a first pushing device and a second pushing device, the first pushing device is used for pushing the assembly on the assembly station table in the first magnetic buckle assembling device into the first conveying channel and pushing the assembly to the first buckle pressing station through the first conveying channel, and the second pushing device is used for pushing the assembly on the assembly station table in the second magnetic buckle assembling device into the second conveying channel and pushing the assembly to the second buckle pressing station through the second conveying channel; the two feeding devices are respectively a first feeding device and a second feeding device, the first feeding device is used for conveying the workpiece D to the first buckling station, and the second feeding device is used for conveying the workpiece D to the second buckling station; and the pressing and buckling device 3 is used for pressing and buckling the workpiece C and the workpiece D on the first pressing and buckling station and the second pressing and buckling station with the assembly. The arrangement of the structure can realize synchronous processing work of the left door curtain and the right door curtain on one production line, and effectively improves the production efficiency.

In this embodiment, the first conveyor line 101 includes a first driving pulley, a first driven pulley, and a first conveyor belt 1011 connecting the first driving pulley and the first driven pulley; the second conveying line 102 comprises a second driving pulley, a second driven pulley and a second conveying belt 1021 for connecting the second driving pulley and the second driven pulley, and a driving shaft 10 for connecting the second driving pulley and the first driving pulley is arranged between the second driving pulley and the first driving pulley; the first conveyor line 101 or the second conveyor line 102 further includes a second drive mechanism connected to the drive shaft 10 for driving the rotation of the drive shaft 10. The arrangement of the structure enables the first conveying line 101 and the second conveying line 102 to share one power source, so that the cost can be saved, the energy consumption can be reduced, and the transmission actions of the first conveying line and the second conveying line can have good consistency.

In this embodiment, a first synchronizing wheel and a second synchronizing wheel arranged at intervals along the conveying direction of the first conveying belt 1011, and a first synchronizing belt 11 connecting the first synchronizing wheel and the second synchronizing wheel are arranged above the first conveying belt; a third synchronizing wheel and a fourth synchronizing wheel which are arranged along the conveying direction of the second conveying belt 1021 at intervals, and a second synchronous belt 12 for connecting the third synchronizing wheel and the fourth synchronizing wheel are arranged above the second conveying belt 1021; a first rotating shaft 13 fixedly connected with the first synchronizing wheel and the third synchronizing wheel is arranged between the first synchronizing wheel and the third synchronizing wheel, and a second rotating shaft 14 fixedly connected with the second synchronizing wheel and the fourth synchronizing wheel is arranged between the second synchronizing wheel and the fourth synchronizing wheel; the first rotating shaft 13 or the second rotating shaft 14 is connected to the driving shaft 10 via a transmission mechanism including a fifth pulley fixedly mounted on the first rotating shaft 13 or the second rotating shaft 14, a sixth pulley fixedly mounted on the driving shaft 10, and a third timing belt 15 connecting the fifth pulley and the sixth pulley, and rotates with the rotation of the driving shaft 10. The arrangement of the first synchronous belt 11 and the second synchronous belt 12 can effectively ensure the smoothness of the movement of the gauze.

Referring to fig. 5-6, the feeding mechanism 6 is located on one side of the assembly station platform away from the material loading platform 5, the feeding mechanism 6 includes a vibrating disk a601, a feeding channel 602, and a material pushing assembly 603, wherein: the material pushing assembly 603 is located on one side of the assembling station platform, and the material pushing assembly 603 comprises a material pushing block and a power unit C for driving the material pushing block to perform linear reciprocating motion towards the assembling station platform; the feeding channel 602 is located between the pushing assembly 603 and the assembling workbench, one end of the feeding channel 602 is in butt joint with the discharge port of the vibrating disc a601, and the other end of the feeding channel is located between the pushing block and the assembling workbench. In the work, the lower cover used for processing the magnetic buckle is put in the vibration disc A in advance, and when the lower cover in the vibration disc A moves to a position between the material pushing assembly 603 and the assembling station table through the feeding channel 602, the material pushing assembly 603 is used for pushing the lower cover to the assembling station table.

In this embodiment, the propelling mechanism 7 includes a magnetic propelling block and a power unit a connected to the propelling block, the propelling block includes a strong magnet, the propelling block is located at one side of each material storage tank 501 close to the material outlet thereof and is driven by the power unit a to perform linear reciprocating motion along the motion direction of the material loading platform 5; the assembling station platform is positioned at one end of the motion direction of the propelling block. The pressing mechanism 8 comprises an upper pressing block 801 positioned above the assembling station table and a power unit B802 used for driving the upper pressing block 801 to reciprocate up and down, wherein the upper pressing block 801 is made of a ferromagnetic material. In operation, when the pushing block moves to the discharge port of the material storage tank 501, the magnetic block in the material storage tank 501 is sucked out by the magnetism of the pushing block and pushed to the upper side of the assembling station table and automatically adsorbed to the upper pressing block 801, and when the upper pressing block 801 moves downwards, the magnetic block can be automatically pressed into the lower cover on the assembling station table to form a combination of the magnetic block and the lower cover.

Referring to fig. 7 to 8, the feeding device includes a first feeding path 17, a second feeding path 18, and a vibration disk B19, wherein: one end of the first feeding channel 17 is provided with a feeding platform 20 butted with the first feeding channel, and one end of the first feeding channel far away from the feeding platform 20 extends to the pressing and buckling station platform 4; the second feeding channel 18 is positioned on one side of the extending direction of the first feeding channel 17 and extends in the same direction as the first feeding channel 17, one end of the second feeding channel 18 is in butt joint with the discharge hole of the vibrating disc B19, and the other end of the second feeding channel 18 is parallel to the conveying direction of the first feeding channel 17 and is in butt joint with the feeding table 20; a first feeding push block 21 and a power unit E22 for driving the first feeding push block 21 to perform linear reciprocating motion towards the first feeding channel 17 are arranged at one end, far away from the first feeding channel 17, of the feeding table 20; a second feeding push block 23 arranged opposite to the feeding table 20 and a power unit F24 for driving the second feeding push block 23 to perform linear reciprocating motion towards the feeding table 20 are arranged on one side, away from the feeding table 20, of the second feeding channel 18; the height of one end of the conveying channel 2, which is butted with the pressing and buckling station table 4, is lower than the height of one end of the first feeding channel 17, which extends to the pressing and buckling station table 4. During working, an upper cover for processing the magnetic buckle is placed in the vibrating disc B in advance, when a lower cover in the vibrating disc B moves to the feeding table 20 through the second feeding channel 18, the upper cover is pushed to a position between the first feeding push block 21 and the first feeding channel 17 by matching of the power unit F24 and the second feeding push block 23, then the upper cover is pushed to the first feeding channel 17 by matching of the power unit E22 and the first feeding channel 17, and the upper cover arranged at the foremost end is automatically pushed to the pressing buckle working table along with continuous entering of the upper cover in the first feeding channel 17.

Referring to fig. 9-10, the fastening device 3 includes an upper fastening plate 301 and a first driving mechanism 302 connected to the upper fastening plate 301, the upper fastening plate 301 is located above the fastening station platform 4, and the first driving mechanism 302 is fixedly mounted on the fastening station platform 4 for driving the upper fastening plate 301 to reciprocate up and down, so that the upper fastening plate 301 is utilized to fasten the workpieces on the fastening station platform 4 together on the gauze.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (17)

1. The utility model provides an automatic dress of door curtain detains production line which characterized in that includes: transfer chain (1), magnetism detain assembly device, transfer passage (2), pusher (16), loading attachment and press and detain device (3), wherein:

a pressing and buckling station table (4) is arranged on one side of the conveying direction of the conveying line (1);

the magnetic buckle assembling device comprises a material loading platform (5), a feeding mechanism (6), a propelling mechanism (7), a pressing mechanism (8) and a power mechanism (9); the material loading platform (5) is connected with the power mechanism (9) and driven by the power mechanism (9) to perform linear reciprocating motion, an assembly station platform is arranged on one side of the motion direction of the material loading platform (5), a plurality of material storage grooves (501) used for storing workpieces A are formed in the material loading platform (5), the material storage grooves (501) are arranged in parallel along the motion direction of the material storage grooves, and one end, close to the assembly station platform, of each material storage groove (501) is opened to form a discharge hole; the feeding mechanism (6) is used for conveying the workpiece B to the assembling station table; the pushing mechanism (7) is used for pushing the workpiece A in the storage tank (501) to the upper part of the assembling station table; the pressing mechanism (8) is positioned above the assembly station table and used for pressing the workpiece A on the assembly station table into the workpiece B to form an assembly;

one end of the conveying channel (2) is butted with the assembling station platform, and the other end of the conveying channel is butted with the pressing and buckling station platform (4);

the pushing device (16) is used for pushing the assembly on the assembling station platform into the conveying channel (2) and pushing the assembly to the pressing and buckling station platform (4) through the conveying channel (2);

the conveying line (1) is used for conveying the workpiece C to the pressing and buckling station table (4);

the feeding device is used for conveying the workpiece D to the pressing and buckling station table (4);

the pressing and buckling device (3) is positioned at the pressing and buckling station table (4) and is used for pressing and buckling the workpiece C and the workpiece D on the pressing and buckling station table (4) and the assembly.

2. The automatic door curtain buckling production line according to claim 1, wherein the feeding mechanism (6) comprises a vibrating disk A (601), a feeding channel (602) and a pushing assembly (603), wherein: the material pushing assembly (603) is positioned on one side of the assembling station platform, and the material pushing assembly (603) comprises a material pushing block and a power unit C for driving the material pushing block to perform linear reciprocating motion towards the assembling work platform; one end of the feeding channel (602) is in butt joint with a discharge hole of the vibrating disc A (601), and the other end of the feeding channel is located between the material pushing block and the assembling station table.

3. The automatic door curtain buckling production line as claimed in claim 2, wherein the feeding channel (602) is positioned between the pushing assembly (603) and the assembling workbench, and the extension direction of the feeding channel (602) is parallel to the movement direction of the material loading platform (5).

4. The automatic door curtain buckling production line as claimed in claim 3, wherein the feeding mechanism (6) is positioned on one side of the assembling station platform far away from the material loading platform (5).

5. The automatic door curtain buckling production line according to claim 1, wherein the pushing mechanism (7) comprises a magnetic pushing block and a power unit A connected with the pushing block, the pushing block is positioned on one side of each storage tank (501) close to the discharge port of the storage tank and is driven by the power unit A to perform linear reciprocating motion along the motion direction of the material loading platform (5); the assembling station platform is positioned at one end of the motion direction of the propelling block.

6. The automatic door curtain threading line of claim 5, wherein the pusher block comprises a powerful magnet.

7. The automatic door curtain buckling production line as claimed in claim 1, wherein the pressing mechanism (8) comprises an upper pressing block (801) located above the assembly station table and a power unit B (802) used for driving the upper pressing block (801) to reciprocate up and down, and the upper pressing block (801) is made of a ferromagnetic material.

8. The automatic door curtain buckling production line as claimed in claim 1, wherein the pushing device (16) comprises a pushing block and a power unit D connected with the pushing block, the pushing block is positioned on one side of the conveying channel (2) far away from the assembling station table and is driven by the power unit D to perform linear reciprocating motion towards the conveying channel (2).

9. The automatic door curtain fastening production line according to claim 1, wherein the feeding device comprises a first feeding channel (17), a second feeding channel (18) and a vibrating plate B (19), wherein: one end of the first feeding channel (17) is provided with a feeding platform (20) which is in butt joint with the first feeding channel, and the end of the first feeding channel, which is far away from the feeding platform (20), extends to the pressing and buckling station platform (4); the second feeding channel (18) is positioned on one side of the extending direction of the first feeding channel (17) and extends in the same direction as the first feeding channel (17), one end of the second feeding channel (18) is in butt joint with a discharge hole of the vibrating disc B (19), and the other end of the second feeding channel is parallel to the conveying direction of the first feeding channel (17) and is in butt joint with the feeding table (20); one end of the feeding platform (20) far away from the first feeding channel (17) is provided with a first feeding push block (21) and a power unit E (22) for driving the first feeding push block (21) to do linear reciprocating motion towards the first feeding channel (17); one side of the second feeding channel (18) far away from the feeding table (20) is provided with a second feeding push block (23) arranged opposite to the feeding table (20) and a power unit F (24) used for driving the second feeding push block (23) to perform linear reciprocating motion towards the feeding table (20).

10. The automatic door curtain buckling production line as claimed in claim 9, wherein the height of the butt joint end of the conveying channel (2) and the buckling station platform (4) is lower than the height of the first feeding channel (17) extending to one end of the buckling station platform (4).

11. The automatic door curtain fastening production line according to claim 1, wherein the fastening device (3) comprises an upper fastening plate (301) and a first driving mechanism (302) connected with the upper fastening plate (301), and the upper fastening plate (301) is located above the fastening station table (4) and driven by the first driving mechanism (302) to reciprocate up and down.

12. An automatic door curtain fastening production line according to claim 11, wherein the first driving mechanism (302) is fixedly arranged on the fastening station table (4).

13. The automatic door curtain threading line according to claim 1, characterized in that the output end of the conveyor line (1) is provided with a blanking robot (25) for transferring material out of the conveyor line (1).

14. The automatic door curtain buckling production line according to any one of claims 1 to 13, wherein the conveying line (1) comprises a first conveying line (101) and a second conveying line (102), the first conveying line (101) and the second conveying line (102) are arranged in parallel, the buckling station table (4) is positioned between the first conveying line (101) and the second conveying line (102), a first buckling station is arranged on one side, close to the first conveying line (101), of the upper table top of the buckling station table (4), and a second buckling station is arranged on one side, close to the second conveying line (102), of the upper table top of the buckling station table (4); the two magnetic buckle assembling devices are respectively a first magnetic buckle assembling device and a second magnetic buckle assembling device, the first magnetic buckle assembling device is positioned on one side of the first conveying line (101) far away from the second conveying line (102), and the second magnetic buckle assembling device is positioned on one side of the second conveying line (102) far away from the first conveying line (101); two conveying channels (2) are respectively a first conveying channel and a second conveying channel, one end of the first conveying channel is in butt joint with an assembly station table in the first magnetic buckle assembly device, the other end of the first conveying channel is in butt joint with a first buckle pressing station in the buckle pressing station table (4), one end of the second conveying channel is in butt joint with an assembly station table in the second magnetic buckle assembly device, and the other end of the second conveying channel is in butt joint with a second buckle pressing station in the buckle pressing station table (4); the two pushing devices (16) are respectively a first pushing device and a second pushing device, the first pushing device is used for pushing the assembly on the assembly station table in the first magnetic buckle assembling device into the first conveying channel and pushing the assembly to the first buckle pressing station through the first conveying channel, and the second pushing device is used for pushing the assembly on the assembly station table in the second magnetic buckle assembling device into the second conveying channel and pushing the assembly to the second buckle pressing station through the second conveying channel; the two feeding devices are respectively a first feeding device and a second feeding device, the first feeding device is used for conveying the workpiece D to the first buckling station, and the second feeding device is used for conveying the workpiece D to the second buckling station; and the pressing and buckling device (3) is used for pressing and buckling the workpieces C and D on the first pressing and buckling station and the second pressing and buckling station with the assembly.

15. The automatic door curtain attaching and fastening production line according to claim 14, wherein the first conveying line (101) comprises a first driving pulley, a first driven pulley and a first conveying belt (1011) connecting the first driving pulley and the first driven pulley; the second conveying line (102) comprises a second driving belt wheel, a second driven belt wheel and a second conveying belt (1021) for connecting the second driving belt wheel and the second driven belt wheel, and a driving shaft (10) for connecting the second driving belt wheel and the first driving belt wheel is arranged between the second driving belt wheel and the first driving belt wheel; the first conveyor line (101) or the second conveyor line (102) further comprises a second drive mechanism connected with the drive shaft (10) for driving the rotation of the drive shaft (10).

16. The automatic door curtain attaching and fastening production line as claimed in claim 15, wherein a first synchronizing wheel, a second synchronizing wheel and a first synchronizing belt (11) connecting the first synchronizing wheel and the second synchronizing wheel are arranged above the first conveyor belt (1011) at intervals along the conveying direction; a third synchronizing wheel and a fourth synchronizing wheel which are arranged along the conveying direction of the second conveying belt (1021) at intervals, and a second synchronous belt (12) connecting the third synchronizing wheel and the fourth synchronizing wheel are arranged above the second conveying belt (1021); a first rotating shaft (13) fixedly connected with the first synchronizing wheel and the third synchronizing wheel is arranged between the first synchronizing wheel and the third synchronizing wheel, and a second rotating shaft (14) fixedly connected with the second synchronizing wheel and the fourth synchronizing wheel is arranged between the second synchronizing wheel and the fourth synchronizing wheel; the first rotating shaft (13) or the second rotating shaft (14) is connected with the driving shaft (10) through a transmission mechanism and rotates along with the rotation of the driving shaft (10).

17. The automatic door curtain threading production line according to claim 16, wherein the transmission mechanism comprises a fifth pulley fixedly mounted on the first rotation shaft (13) or the second rotation shaft (14), a sixth pulley fixedly mounted on the drive shaft (10), and a third timing belt (15) connecting the fifth pulley and the sixth pulley.

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