CN215356750U - Double-station panel laser cutting machine - Google Patents

Abstract

The utility model discloses a double-station panel laser cutting machine which comprises a supporting platform, a first processing platform, a second processing platform, a feeding assembly and a laser processing assembly, wherein the first processing platform is arranged on the supporting platform; the first processing platform and the second processing platform are adjacently arranged on the supporting platform; the feeding assembly is used for conveying the workpieces placed on the feeding assembly to the first processing platform and the second processing platform, and the laser processing assembly is used for processing the workpieces on the first processing platform and the second processing platform. Through setting up first processing platform and second processing platform, can realize duplex position mode of processing to work efficiency has been improved, and with the adjacent setting on supporting platform of first processing platform and second processing platform, can be close to as far as possible two processing stations, reduced supporting platform's width, thereby make duplex position panel laser cutting machine's whole volume littleer, also reduced supporting platform's quantity, the packing of being more convenient for tear open when tearing open the machine packing, and also more convenient the machine that resumes.

Description

Double-station panel laser cutting machine

Technical Field

The utility model belongs to the technical field of liquid crystal panel processing equipment, and particularly relates to a double-station panel laser cutting machine.

Background

The existing liquid crystal panel needs to cut a short circuit ring on a panel main body of the liquid crystal panel, the short circuit ring is generally cut by panel short circuit ring cutting equipment, and in order to meet the production efficiency of the equipment on a production line, the panel short circuit ring cutting equipment is designed into a double-station mode so as to achieve faster production efficiency. With the continuous development of the panel industry, the larger the panel size is, the more the panel size is, the platform must be divided into two parts according to the traditional design scheme, as shown in fig. 1, each station needs an independent marble platform 1 ' to be built, the marble platforms 1 ' are arranged at intervals from left to right, a channel for placing a feeding device 2 ' is arranged at intervals in the middle, and then a feeding mechanism 3 ' on the marble platform 1 ' picks materials from the feeding device 2 ', the design scheme has the advantages that one more marble platform is added, and a laser cutting assembly 4 ' is arranged on each marble platform, so that the equipment cost is high, and the competitiveness of the equipment is reduced; because the platform adopts two designs, the equipment must be dismantled and independently packed when sending out the machine, wastes time and energy, for the staff of customer scene, has also increased certain difficulty when the machine is recovered.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is as follows: aiming at the problem of large volume of the existing double-station panel laser cutting machine, the double-station panel laser cutting machine is provided.

In order to solve the technical problem, the embodiment of the utility model provides a double-station panel laser cutting machine which comprises a supporting platform, a first processing platform, a second processing platform, a feeding assembly and a laser processing assembly, wherein the first processing platform is arranged on the supporting platform; the first processing platform and the second processing platform are adjacently arranged on the supporting platform;

the feeding assembly is used for conveying the workpieces placed on the feeding assembly to the first processing platform and the second processing platform, and the laser processing assembly is used for processing the workpieces on the first processing platform and the second processing platform.

Optionally, the double-station panel laser cutting machine further comprises a discharging assembly and a discharging assembly, wherein the discharging assembly is used for conveying the workpieces processed on the first processing platform and the second processing platform to the discharging assembly for discharging.

Optionally, the double-station panel laser cutting machine further comprises a first driving assembly and a second driving assembly, and the first processing platform and the second processing platform are slidably arranged on the supporting platform;

the first driving assembly is used for driving the first processing platform to slide so that the first processing platform can be switched back and forth at a first feeding station, a first processing station and a first discharging station;

the second driving assembly is used for driving the second machining platform to slide so that the second machining platform can be switched back and forth at a second feeding station, a second machining station and a second discharging station.

Optionally, a support column for supporting a workpiece is disposed on each of the first processing platform and the second processing platform.

Optionally, the feeding assembly is arranged on one side of the supporting platform, and the feeding assembly comprises a feeding frame, a first rotating shaft rotatably arranged on the feeding frame, and a third driving assembly for driving the first rotating shaft to rotate; the first rotating shaft is used for supporting a workpiece and can move the workpiece when rotating.

Optionally, the feeding assembly includes a first gantry, a fourth driving assembly and a first chuck assembly, the fourth driving assembly is disposed on the first gantry, and the fourth driving assembly is configured to drive the first chuck assembly to convey the workpiece placed on the feeding assembly to the first processing platform and the second processing platform.

Optionally, the laser processing assembly comprises a second gantry, a fifth driving assembly and a laser head assembly, the fifth driving assembly is arranged on the second gantry, and the fifth driving assembly is used for driving the laser head assembly to move above the first processing platform and above the second processing platform;

the laser head assembly is used for processing a workpiece on the first processing platform when the laser head assembly is positioned above the first processing platform; and when the laser head assembly is positioned above the second processing platform, the laser head assembly is used for processing the workpiece on the second processing platform.

Optionally, the laser processing assembly further comprises a positioning CCD assembly for acquiring position information of the workpiece, and the positioning CCD assembly is disposed on the second gantry.

Optionally, the discharging assembly is arranged on one side of the supporting platform, and the discharging assembly comprises a discharging frame, a second rotating shaft rotatably arranged on the discharging frame, and a sixth driving assembly for driving the second rotating shaft to rotate; the second rotating shaft is used for supporting a workpiece and enabling the workpiece to move when the second rotating shaft rotates.

Optionally, the blanking assembly comprises a third portal frame, a seventh driving assembly and a second sucker assembly, the seventh driving assembly is arranged on the third portal frame, and the seventh driving assembly is used for driving the second sucker assembly to convey the workpiece on the first processing platform and the workpiece on the second processing platform to the discharging assembly.

Compared with the prior art, the double-station panel laser cutting machine provided by the embodiment of the utility model has the advantages that the double-station processing mode can be realized by arranging the first processing platform and the second processing platform, so that the working efficiency is improved, the first processing platform and the second processing platform are adjacently arranged on the supporting platform, the two processing stations can be close to each other as much as possible, the width of the supporting platform is reduced, the integral volume of the double-station panel laser cutting machine is smaller, the distance between the two processing stations is smaller by the aid of the adjacently arranged first processing platform and the second processing platform, the time for the laser processing assembly to work back and forth on the two processing stations is shortened, and the processing efficiency is further improved. Because first processing platform and second processing platform set up on same supporting platform, reduced supporting platform's quantity to equipment cost has been reduced, and also reduced the quantity of independent packing when the bale breaking, the bale breaking of being more convenient for is packed, and also more convenient the machine (assembles into finished product machine).

Drawings

Fig. 1 is a schematic structural view of a conventional panel short ring cutting apparatus;

fig. 2 is a schematic structural diagram of a double-station panel laser cutting machine according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of another view angle of the double-station panel laser cutting machine provided by the embodiment of the utility model;

fig. 4 is a schematic structural diagram of another view angle of the double-station panel laser cutting machine according to the embodiment of the present invention;

fig. 5 is an enlarged view at B of fig. 4;

FIG. 6 is an enlarged view at A of FIG. 2;

FIG. 7 is an enlarged view at C of FIG. 4;

fig. 8 is a schematic structural diagram of a laser processing assembly according to an embodiment of the present invention.

The reference numerals in the specification are as follows:

1. a support platform;

2. a first processing platform;

3. a second processing platform;

4. a feeding assembly; 41. feeding a material frame; 42. a first rotating shaft; 43. a third drive assembly; 431. a first drive shaft; 432. a first magnetic wheel; 433. a second magnetic wheel;

5. a feeding assembly; 51. a first gantry; 52. a fourth drive assembly; 521. a first horizontal drive assembly; 522. a first vertical drive assembly; 53. a first suction cup assembly; 531. a first suction cup frame; 532. a first suction cup;

6. a laser processing assembly; 61. a second gantry; 62. a fifth drive assembly; 63. a laser head assembly; 631. a laser cutting head; 632. a laser; 64. positioning the CCD assembly; 641. a CCD camera; 642. a CCD horizontal driving component; 643. a CCD vertical driving assembly;

7. a blanking assembly; 71. a third portal frame; 72. a seventh drive assembly; 73. a second chuck assembly;

8. a discharge assembly; 81. a discharging frame;

9. a first drive assembly; 10. a second drive assembly; 20. and (4) a support column.

Detailed Description

In order to make the technical problems, technical solutions and advantageous effects solved by the present invention more clearly apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and are not intended to limit the utility model.

As shown in fig. 2, the double-station panel laser cutting machine provided by the embodiment of the utility model comprises a supporting platform 1, a first processing platform 2, a second processing platform 3, a feeding assembly 4, a feeding assembly 5 and a laser processing assembly 6; the first processing platform 2 and the second processing platform 3 are adjacently arranged on the supporting platform 1;

the feeding assembly 5 is used for conveying the workpieces placed on the feeding assembly 4 to the first processing platform 2 and the second processing platform 3, and the laser processing assembly 6 is used for processing the workpieces on the first processing platform 2 and the second processing platform 3.

Wherein, supporting platform 1 can adopt the marble platform, and stability and intensity are better.

When the workpiece needs to be machined, the workpiece placed on the feeding assembly 4 is conveyed to the first machining platform 2 and the second machining platform 3 by the feeding assembly 5, and then the workpiece on the first machining platform 2 and the second machining platform 3 is machined by the laser machining assembly 6. Wherein the laser machining assembly 6 can be switched back and forth between the first machining platform 2 and the second machining platform 3 for machining workpieces on the first machining platform 2 and the second machining platform 3, respectively.

Compared with the prior art, the double-station panel laser cutting machine provided by the embodiment of the utility model has the advantages that the double-station processing mode can be realized by arranging the first processing platform 2 and the second processing platform 3, so that the working efficiency is improved, in addition, the first processing platform 2 and the second processing platform 3 are adjacently arranged on the supporting platform 1, the two processing stations can be close to each other as much as possible, the width of the supporting platform 1 is reduced, the integral volume of the double-station panel laser cutting machine is smaller, in addition, the distance between the two processing stations is smaller due to the adjacent arrangement of the first processing platform 2 and the second processing platform 3, the time for the laser processing assembly 6 to work back and forth at the two processing stations is reduced, and the processing efficiency is further improved. Because first processing platform 2 and second processing platform 3 set up on same supporting platform 1, reduced supporting platform 1's quantity to equipment cost has been reduced, and also reduced the quantity of independent packing when the bale breaking, the bale breaking of being more convenient for is packed, and also more makes things convenient for the machine (assembles into finished product machine).

In an embodiment, as shown in fig. 2, the double-station panel laser cutting machine further includes a blanking assembly 7 and a discharging assembly 8, where the blanking assembly 7 is used to transport the processed workpieces on the first processing platform 2 and the second processing platform 3 to the discharging assembly 8 for discharging. The processed workpiece can be conveniently transported out by arranging the blanking assembly 7 and the discharging assembly 8.

In an embodiment, as shown in fig. 3, the double-station panel laser cutting machine further includes a first driving assembly 9 and a second driving assembly 10, wherein the first processing platform 2 and the second processing platform 3 are slidably disposed on the supporting platform 1;

the first driving assembly 9 is used for driving the first processing platform 2 to slide so that the first processing platform 2 can be switched back and forth among the first feeding station, the first processing station and the first discharging station;

the second driving assembly 10 is used for driving the second processing platform 3 to slide, so that the second processing platform 3 can be switched back and forth among the second feeding station, the second processing station and the second discharging station. Through setting up first drive assembly 9 and second drive assembly 10, can make things convenient for first processing platform 2 and second processing platform 3 to switch on each station.

Specifically, when the machining process is started, the first machining platform 2 is located at a first feeding station, the second machining platform 3 is located at a second feeding station, the workpiece placed on the feeding assembly 4 is conveyed to the first machining platform 2 and the second machining platform 3 by the feeding assembly 5 for feeding, the first driving assembly 9 drives the first machining platform 2 to slide to the first machining station, the second driving assembly 10 drives the second machining platform 3 to slide to the second machining station, the workpiece on the first machining platform 2 and the second machining platform 3 is machined by the laser machining assembly 6, and after the machining of the workpiece is finished, the first driving assembly 9 drives the first processing platform 2 to slide to the first blanking station, the second driving assembly 10 drives the second processing platform 3 to slide to the second blanking station, and the workpieces processed on the first processing platform 2 and the second processing platform 3 are conveyed to the discharging assembly 8 by the blanking assembly 7 to be discharged.

Preferably, the first driving assembly 9 and the second driving assembly 10 can adopt a linear module, and the first processing platform 2 and the second processing platform 3 are driven to move by the linear module (namely, a linear motor), so that the linear precision is higher, and the processing requirement can be met.

In one embodiment, as shown in fig. 4, support columns 20 for supporting the workpiece are provided on both the first processing platform 2 and the second processing platform 3. The support of the workpiece is facilitated by the provision of the support posts 20.

Preferably, a vacuum chuck can be arranged on the supporting column 20, and the workpiece can be positioned more stably on the processing platform (the first processing platform 2 and the second processing platform 3) by sucking the workpiece through the vacuum chuck, so that the processing precision is higher. Wherein, when unloading subassembly 7 will shift out the work piece after the processing on first processing platform 2 and on the second processing platform 3, the broken vacuum of vacuum chuck on the processing platform removes the location to make things convenient for the work piece to shift out first processing platform 2 and second processing platform 3.

In an embodiment, as shown in fig. 4 and 5, the feeding assembly 4 is disposed at one side of the supporting platform 1, and the feeding assembly 4 includes a feeding frame 41, a first rotating shaft 42 rotatably disposed on the feeding frame 41, and a third driving assembly 43 for driving the first rotating shaft 42 to rotate; the first rotating shaft 42 is for supporting a workpiece and the workpiece can be moved when the first rotating shaft 42 is rotated. The first rotating shaft 42 is driven to rotate by the third driving assembly 43 to facilitate the workpiece transfer.

Preferably, the third driving assembly 43 adopts magnetic wheel transmission, the third driving assembly 43 includes a first transmission shaft 431 and a first motor (not shown in the drawings), the first motor is used for driving the first transmission shaft 431 to rotate, a first magnetic wheel 432 is arranged on the first transmission shaft 431, a second magnetic wheel 433 is arranged at one end of the first transmission shaft 42, the first magnetic wheel 432 and the second magnetic wheel 433 are correspondingly arranged, the first motor drives the first transmission shaft 431 to rotate through a transmission mechanism, so that the first transmission shaft 42 is driven to rotate through the magnetic action of the first magnetic wheel 432 and the second magnetic wheel 433, and by adopting the magnetic wheel transmission mode, the power transmission capability is high, no noise is generated, and the installation is easy. The magnetic wheel may be a conventional magnetic wheel, and therefore the operation principle thereof is not described herein. The motor shaft of the first motor may be directly and fixedly connected to the first transmission shaft 431, or the first motor may drive the first transmission shaft 431 to rotate through a conventional transmission manner such as gear transmission or belt transmission.

Preferably, a positioning jig for positioning the workpiece is arranged on the feeding assembly 4.

In one embodiment, as shown in fig. 2 and 6, the feeding assembly 5 includes a first gantry 51, a fourth driving assembly 52 and a first chuck assembly 53, the fourth driving assembly 52 is disposed on the first gantry 51, and the fourth driving assembly 52 is configured to drive the first chuck assembly 53 to transfer the workpiece placed on the feeding assembly 4 to the first processing platform 2 and the second processing platform 3.

The fourth driving assembly 52 comprises a first horizontal driving assembly 521 and a first vertical driving assembly 522, the first horizontal driving assembly 521 is arranged on the first portal frame 51, the first vertical driving assembly 522 is arranged at an output end of the first horizontal driving assembly 521, the first chuck assembly 53 is arranged at an output end of the first vertical driving assembly 522, the first horizontal driving assembly 521 is used for driving the first vertical driving assembly 522 and the first chuck assembly 53 to move horizontally together, the first vertical driving assembly 522 is used for driving the first chuck assembly 53 to move vertically, and through mutual matching of the first horizontal driving assembly 521 and the first vertical driving assembly 522, the first chuck assembly 53 sucks a workpiece from the feeding assembly 4 and conveys the workpiece to the first processing platform 2 and the second processing platform 3. The first horizontal driving assembly 521 may be a linear module, and the first vertical driving assembly 522 may also be a linear module, which is not limited herein as long as the driving function is provided.

In one embodiment, as shown in fig. 6, the first suction cup assembly 53 includes a first suction cup frame 531 and a first suction cup 532, the first suction cup frame 531 is disposed at the output end of the first vertical driving assembly 522, the first suction cup 532 is disposed on the first suction cup frame 531, and the suction action is performed by the first suction cup 532.

In one embodiment, as shown in fig. 8, the laser processing assembly 6 includes a second gantry 61, a fifth driving assembly 62 and a laser head assembly 63, the fifth driving assembly 62 is disposed on the second gantry 61, and the fifth driving assembly 62 is used for driving the laser head assembly 63 to move above the first processing platform 2 and above the second processing platform 3;

when the laser head assembly 63 is positioned above the first processing platform 2, the laser head assembly 63 is used for processing a workpiece on the first processing platform 2; the laser head assembly 63 is used to machine a workpiece on the second machining platform 3 when the laser head assembly 63 is positioned above the second machining platform 3. Wherein, the fifth driving assembly 62 can adopt a linear module, and the laser head assembly 63 is driven by the linear module to move horizontally.

In an embodiment, as shown in fig. 8, the laser head assembly 63 includes a laser cutting head 631 and a laser 632, the laser 632 is disposed on the second gantry 61, the laser cutting head 631 is disposed at an output end of the fifth driving assembly 62 and is driven by the fifth driving assembly 62 to move, and the laser 632 is configured to emit laser to the laser cutting head 631, so as to implement a cutting function through the laser cutting head 631.

In one embodiment, as shown in fig. 7 and 8, the laser processing assembly 6 further includes a positioning CCD assembly 64 for acquiring position information of the workpiece, and the positioning CCD assembly 64 is disposed on the second gantry 61. The position information of the workpiece can be acquired by arranging the positioning CCD assembly 64 and fed back to the control device, and the control device controls the laser head assembly 63 to cut the workpiece according to the information fed back by the positioning CCD assembly 64. The information feedback and information processing of the positioning CCD assembly 64 are prior art, and the present invention is not developed herein.

In an embodiment, as shown in fig. 7, the positioning CCD assembly 64 includes a CCD camera 641, a CCD horizontal driving assembly 642 and a CCD vertical driving assembly 643, the CCD horizontal driving assembly 642 is disposed on the second gantry 61, the CCD vertical driving assembly 643 is disposed at an output end of the CCD horizontal driving assembly 642, the CCD camera 641 is disposed at an output end of the CCD vertical driving assembly 643, and the CCD horizontal driving assembly 642 is used for driving the CCD vertical driving assembly 643 and the CCD camera 641 to move horizontally together, so that the CCD camera 641 can be switched back and forth between the first processing platform 2 and the second processing platform 3 to obtain the position information of the workpiece on the respective processing platform. The CCD vertical driving assembly 643 is used for driving the CCD camera 641 to move in the vertical direction so as to adjust the distance between the CCD camera 641 and the workpiece, so as to achieve the best fixed focus.

Wherein the CCD horizontal driving assembly 642 and the CCD vertical driving assembly 643 can adopt a linear module. The utility model is not limited thereto, as long as it can function as a drive

Specifically, the laser cutting head 631 and the positioning CCD assembly 64 are respectively disposed on two opposite sides of the second portal frame 61, the positioning CCD assembly 64 is disposed on one side of the second portal frame 61 facing the feeding station, and the laser cutting head 631 is disposed on one side of the second portal frame 61 facing away from the feeding station.

In one embodiment, as shown in FIG. 3, the outfeed assembly 8 is positioned on one side of the support platform 1. Preferably, the discharging assembly 8 is arranged at the same side of the supporting platform 1 as the feeding assembly 4, so that the space can be saved.

The discharging assembly 8 may have a structure similar to that of the feeding assembly 4, and the discharging assembly 8 includes a discharging rack 81, a second rotating shaft (not shown in the drawings) rotatably disposed on the discharging rack 81, and a sixth driving assembly (not shown in the drawings) for driving the second rotating shaft to rotate; the second rotating shaft is used for supporting the workpiece and enabling the workpiece to move when the second rotating shaft rotates. The sixth driving component drives the second rotating shaft to rotate so as to facilitate the transmission of the workpiece.

Preferably, the sixth drive assembly adopts the transmission of magnetic force wheel, the sixth drive assembly includes second transmission shaft and second motor (not marked in the drawing), the second motor is used for driving the second transmission shaft and rotates, set up the third magnetic force wheel on the second transmission shaft, serve at one of second axis of rotation and set up the fourth magnetic force wheel, third magnetic force wheel and fourth magnetic force wheel correspond the setting, the second motor passes through drive mechanism and drives the second transmission shaft and rotate, thereby magnetic force effect through third magnetic force wheel and fourth magnetic force wheel drives the second axis of rotation and rotates, through adopting the driven mode of magnetic force wheel, power transmission capacity is high, noiselessness and easily installation. The magnetic wheel may be a conventional magnetic wheel, and therefore the operation principle thereof is not described herein. A motor shaft of the second motor can be directly and fixedly connected with the second transmission shaft, and the second motor can also drive the second transmission shaft to rotate through a conventional transmission mode such as gear transmission or belt transmission.

In one embodiment, as shown in fig. 3, the blanking assembly 7 includes a third gantry 71, a seventh driving assembly 72 and a second suction cup assembly 73, the seventh driving assembly 72 is disposed on the third gantry 71, and the seventh driving assembly 72 is configured to drive the second suction cup assembly 73 to convey the workpiece on the first processing platform 2 and the workpiece on the second processing platform 3 to the discharging assembly 8. The structure of the blanking assembly 7 is similar to that of the loading assembly 5, so the utility model is not developed here.

The present invention is not limited to the above preferred embodiments, and any modifications, equivalent substitutions and improvements made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A double-station panel laser cutting machine is characterized by comprising a supporting platform, a first processing platform, a second processing platform, a feeding assembly and a laser processing assembly; the first processing platform and the second processing platform are adjacently arranged on the supporting platform;

the feeding assembly is used for conveying the workpieces placed on the feeding assembly to the first processing platform and the second processing platform, and the laser processing assembly is used for processing the workpieces on the first processing platform and the second processing platform.

2. The double-station panel laser cutting machine according to claim 1, further comprising a blanking assembly and a discharging assembly, wherein the blanking assembly is used for conveying the processed workpieces on the first processing platform and the second processing platform to the discharging assembly for discharging.

3. The double-station panel laser cutting machine according to claim 2, further comprising a first drive assembly and a second drive assembly, wherein the first machining platform and the second machining platform are slidably disposed on the support platform;

the first driving assembly is used for driving the first processing platform to slide so that the first processing platform can be switched back and forth at a first feeding station, a first processing station and a first discharging station;

the second driving assembly is used for driving the second machining platform to slide so that the second machining platform can be switched back and forth at a second feeding station, a second machining station and a second discharging station.

4. The double-station panel laser cutting machine according to claim 1, wherein support columns for supporting a workpiece are arranged on both the first machining platform and the second machining platform.

5. The double-station panel laser cutting machine according to claim 1, wherein the feeding assembly is arranged on one side of the supporting platform and comprises a feeding frame, a first rotating shaft rotatably arranged on the feeding frame and a third driving assembly for driving the first rotating shaft to rotate; the first rotating shaft is used for supporting a workpiece and can move the workpiece when rotating.

6. The double-station panel laser cutting machine according to claim 1, wherein the feeding assembly comprises a first portal frame, a fourth driving assembly and a first chuck assembly, the fourth driving assembly is arranged on the first portal frame, and the fourth driving assembly is used for driving the first chuck assembly to convey the workpiece placed on the feeding assembly to the first processing platform and the second processing platform.

7. The double-station panel laser cutting machine of claim 1, wherein the laser machining assembly comprises a second gantry, a fifth drive assembly and a laser head assembly, the fifth drive assembly is disposed on the second gantry, and the fifth drive assembly is configured to drive the laser head assembly to move above the first machining platform and above the second machining platform;

the laser head assembly is used for processing a workpiece on the first processing platform when the laser head assembly is positioned above the first processing platform; and when the laser head assembly is positioned above the second processing platform, the laser head assembly is used for processing the workpiece on the second processing platform.

8. The double-station panel laser cutting machine according to claim 7, wherein the laser processing assembly further comprises a positioning CCD assembly for acquiring position information of a workpiece, and the positioning CCD assembly is arranged on the second gantry.

9. The double-station panel laser cutting machine according to claim 2, wherein the discharging assembly is arranged on one side of the supporting platform and comprises a discharging frame, a second rotating shaft rotatably arranged on the discharging frame and a sixth driving assembly for driving the second rotating shaft to rotate; the second rotating shaft is used for supporting a workpiece and enabling the workpiece to move when the second rotating shaft rotates.

10. The double-station panel laser cutting machine according to claim 2, wherein the blanking assembly comprises a third portal frame, a seventh driving assembly and a second suction cup assembly, the seventh driving assembly is arranged on the third portal frame, and the seventh driving assembly is used for driving the second suction cup assembly to convey the workpiece on the first processing platform and the workpiece on the second processing platform to the discharging assembly.

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