Aluminum single plate integrated forming processing line

Abstract

This invention discloses an integrated aluminum panel forming processing line, including a conveying device with multiple parallel drive rollers, each with a processing surface for supporting the aluminum panel; a punching mechanism mounted on the conveying device, comprising a dual-axis linkage assembly and a punching gun; a bending mechanism positioned above the processing surface, comprising two bending drive components and two bending components respectively positioned above the processing surface, the bending drive components driving the bending components to reciprocate in directions approaching and away from the processing surface; and welding robots positioned on opposite sides of the processing surface, with side plate pushing devices positioned between the two welding robots and the opposite sides of the processing surface. This improves aluminum panel production efficiency and reduces labor costs.

Description

Technical Field

[0001] This invention relates to an aluminum plate production equipment, and more particularly to an integrated aluminum single-panel forming processing line. Background Technology

[0002] Aluminum single-layer panels are building decoration materials that have undergone chromating and other treatments, followed by fluorocarbon spraying technology. They have excellent corrosion resistance and weather resistance, can resist acid rain, salt spray and various air pollutants, have excellent resistance to cold and heat, can withstand strong ultraviolet radiation, and can maintain their color and prevent powdering for a long time, with a long service life.

[0003] Currently, there are two main methods for manufacturing aluminum single-layer panels: one is the traditional manual operation method, which involves almost no mechanical equipment; the other is a large-scale pre-roll coating production line. The traditional manual operation method requires high labor costs, and errors can occur at different stages of the production process, and its safety is relatively low.

[0004] To address the problems of traditional manual methods, a new large-scale pre-roll coating production line has been introduced to the market. Compared to traditional aluminum panel spraying processes, pre-roll coating technology significantly reduces energy consumption and labor costs, while increasing production capacity and effectively ensuring appearance quality. Its production efficiency is more than five times that of traditional spraying processes, and the manufacturing cost per square meter of aluminum panel can be reduced by more than 30%. However, the equipment in each production stage of this line is installed separately, making continuous production and one-time forming impossible. Different equipment operates separately for different parts of the aluminum panel and different process stages, making it difficult to produce a one-piece aluminum panel from a single feed, thus failing to meet current societal demands. Summary of the Invention

[0005] In order to overcome the shortcomings of the prior art, the purpose of this invention is to provide an integrated aluminum single-panel forming processing line, which uses a conveying device to transport the panel material and uses production equipment on the conveying device to process the panel, so as to achieve the effect of forming an integrated aluminum single panel in one step and improve production efficiency.

[0006] The objective of this invention is achieved through the following technical solution:

[0007] An integrated aluminum panel forming processing line includes a conveying device, one end of which is a feeding end and the other end of which is a discharging end. The conveying device has multiple parallel drive rollers arranged side-by-side, each with a processing surface for supporting the aluminum panel. A punching mechanism is mounted on the conveying device, comprising a dual-axis linkage assembly and a punching gun. The dual-axis linkage assembly is positioned above the processing surface, and the punching gun is mounted on the dual-axis linkage assembly. A bending mechanism is positioned above the processing surface, comprising two bending drive members and two bending members respectively positioned above the processing surface. The bending drive members can drive the bending members to reciprocate in directions approaching and away from the processing surface. The punching mechanism is positioned on the side of the processing surface relatively closer to the feeding end, and the bending mechanism is positioned on the side of the processing surface relatively closer to the discharging end. Welding robots are respectively positioned on opposite sides of the processing surface, and side plate pushing devices are respectively positioned between the two welding robots and the opposite sides of the processing surface.

[0008] Furthermore, the integrated aluminum panel forming processing line also includes a cutting mechanism, which is located outside the conveying device and connected to the feeding end. The cutting mechanism includes an uncoiler, a leveling machine, and a cutting mechanism. An aluminum coil is installed on the cutting machine, and a leveling platform and a leveling roller are provided on the leveling machine. A leveling gap is formed between the leveling platform and the leveling roller. The leveling machine is located between the uncoiler and the cutting mechanism, and the cutting mechanism is located outside the feeding end and connected to the feeding end.

[0009] Furthermore, the cutting mechanism includes a cutting frame, a conveyor belt, and a cutting mechanism for cutting materials. The conveyor belt is installed on the cutting frame to carry aluminum panels and transport them to the feeding end. The cutting mechanism includes an upper pressure plate and a cutting drive mechanism. The upper pressure plate is disposed above the conveyor belt, and the cutting drive mechanism is connected to the upper pressure plate to drive the upper pressure plate to reciprocate up and down along the height direction of the frame.

[0010] Furthermore, a measuring mechanism is also provided between the leveling machine and the cutting mechanism; the measuring mechanism includes a measuring frame, on which two opposing measuring rollers are provided, and elastic components are respectively connected between the two measuring rollers. The ends of the two elastic components that are far apart from each other are respectively connected to the measuring frame, and the ends of the two elastic components that are close to each other abut against the measuring rollers so that the two measuring rollers collide with each other, and a measuring gap is formed between the measuring rollers for the aluminum single plate to pass through. A displacement sensor is provided between the measuring rollers and the measuring frame; an encoder is provided on the measuring rollers.

[0011] Furthermore, the side plate pushing device includes a base, a fixed platform is provided on the side of the base away from the processing surface, an electric push rod is installed on the fixed platform that can reciprocate in the direction of approaching and moving away from the processing surface, a placement plate is provided on the base, and limit posts are provided on opposite sides of the placement plate.

[0012] Furthermore, the integrated aluminum panel forming processing line also includes a panel cleaning device, which is located outside the conveying device and connected to the discharge end; the panel cleaning device includes a cleaning table, a cleaning roller, and a cleaning roller device connected to the discharge end; the surface of the cleaning table is provided with multiple suction cups, and the cleaning table is provided with a vacuuming device connected to the suction cups; the cleaning roller and the cleaning roller device are both installed on the upper part of the cleaning table and can reciprocate in the direction of approaching and moving away from the surface of the cleaning table.

[0013] Furthermore, the dual-axis linkage mechanism includes an X-axis moving mechanism and a Z-axis moving mechanism; the X-axis moving mechanism is mounted above the processing surface and perpendicular to the line connecting the feed end and the discharge end, the Z-axis moving mechanism is slidably mounted on the X-axis moving mechanism, and the punch is fixedly mounted on the Z-axis moving mechanism.

[0014] Furthermore, there are two Z-axis moving mechanisms, and both Z-axis moving mechanisms are slidably engaged with the X-axis moving mechanism; each end of the X-axis moving mechanism is provided with a limit switch and a limit plate for limiting the travel of the Z-axis moving mechanism; a baffle is also provided between the two Z-axis moving mechanisms to limit the travel of the two Z-axis moving mechanisms and avoid collision and interference between the two Z-axis moving mechanisms.

[0015] Furthermore, the bending drive component includes a bending drive guide rail, a bending cylinder, and a slider that cooperates with the bending drive guide rail; the bending drive guide rail is mounted above the processing surface, and the bending cylinder is fixed to the slider so that the bending cylinder reciprocates along the length direction of the bending drive guide rail via the slider; the piston rod of the bending cylinder is fixedly connected to the bending component; the piston rod of the bending cylinder is perpendicular to the processing surface.

[0016] Furthermore, the bending drive rail is also provided with a plurality of limit sensors arranged along its length; and the opposite ends of the bending drive rail are respectively provided with limit blocks for blocking and limiting the slider.

[0017] Compared with the prior art, the beneficial effects of the present invention are as follows:

[0018] The conveying device is used to support the aluminum single-panel sheet and transport it from the feeding end to the discharging end during the aluminum single-panel production process. The punching mechanism is set on the processing surface relatively close to the feeding end, and can punch holes in the corresponding positions of the aluminum single-panel sheet according to the structural requirements of the aluminum single-panel. The bending mechanism is set on the processing surface relatively close to the discharging end, and can bend the aluminum single-panel sheet in the corresponding positions after punching. The dual-axis linkage assembly for driving the punching gun and the bending drive for controlling the bending parts can meet the needs of different aluminum single-panel structures. Punching and bending can be performed at any position on the surface of the sheet in conjunction with the conveying device.

[0019] Welding robots are installed on opposite sides of the processing surface. The welding robots can push the side plate to the side of the aluminum panel according to the structural requirements of the aluminum panel and perform welding work. This allows multiple processes to be completed in one step. Furthermore, there is no need to move the panels during the production process. The aluminum panels output from the discharge end are integrally formed structures, eliminating the need for secondary processing. This improves the production efficiency of aluminum panels, saves the space required for placing aluminum panel production equipment, and reduces labor costs. Attached Figure Description

[0020] Figure 1 This is a schematic diagram of the overall structure of the aluminum single-panel integrated molding processing line of the present invention;

[0021] Figure 2 This is a schematic diagram of the conveying device structure of the present invention;

[0022] Figure 3 This is a schematic diagram of the cooperative structure of the conveying device, punching mechanism and bending mechanism of the present invention;

[0023] Figure 4 This is a schematic diagram of the punching mechanism of the present invention;

[0024] Figure 5 This is a schematic diagram of the bending mechanism of the present invention;

[0025] Figure 6 This is a schematic diagram of the cutting mechanism structure of the present invention;

[0026] Figure 7 This is a schematic diagram of the side plate pushing device of the present invention;

[0027] Figure 8 This is a schematic diagram of the structure of the panel cleaning device of the present invention.

[0028] In the diagram: 10. Conveying device; 11. Feeding end; 12. Discharging end; 13. Processing surface; 14. Transmission roller; 20. Punching mechanism; 21. Dual-axis linkage assembly; 22. Punching gun; 211. X-axis moving mechanism; 212. Z-axis moving mechanism; 213. Limit switch; 214. Limit plate; 215. Baffle; 30. Bending mechanism; 31. Bending drive component; 32. Bending component; 311. Bending drive guide rail; 312. Bending cylinder; 313. Limit sensor; 314. Limit block; 40. Welding robot; 50. Side plate pushing device; 51. Base; 52. Fixed platform; 53. Electric push rod; 54. Placement plate; 55. Limit post; 60. Cutting mechanism; 61. Uncoiler; 62. Leveling machine; 621. Leveling platform; 622. Leveling pressure roller; 63. Cutting mechanism; 631. Cutting frame; 632. Conveyor belt; 633. Cutting mechanism; 6331. Upper pressure plate; 6332. Cutting drive mechanism; 70. Measuring mechanism; 71. Measuring frame; 72. Measuring roller; 73. Elastic component; 80. Board surface cleaning device; 81. Cleaning table; 811. Suction cup; 82. Cleaning roller; 83. Cleaning roller device. Detailed Implementation

[0029] The present invention will now be further described in conjunction with the accompanying drawings and specific embodiments. It should be noted that, without conflict, the various embodiments or technical features described below can be arbitrarily combined to form new embodiments.

[0030] like Figures 1-5 As shown, in order to improve the production efficiency of aluminum single-panel and save costs, this invention discloses an integrated aluminum single-panel forming processing line, which includes a conveying device 10. One end of the conveying device 10 is a feeding end 11, and the other end of the conveying device 10 is a discharging end 12. The conveying device 10 is provided with a plurality of parallel drive rollers 14. The plurality of drive rollers 14 are formed with processing surfaces 13 for supporting aluminum single-panel. In the actual production process of aluminum single-panel, the aluminum sheet required for producing aluminum single-panel enters the conveying device 10 from the feeding end 11 and is supported on the processing surface 13 by the drive rollers 14. In this example, the roller surfaces of the drive rollers 14 are all covered with an anti-slip layer. By driving the drive rollers 14 to rotate, the aluminum single-panel moves on the processing surface 13.

[0031] The aluminum single-panel integrated forming processing line of the present invention also includes a punching mechanism 20 disposed on the conveying device 10. The punching mechanism 20 includes a dual-axis linkage assembly 21 and a punching gun 22. The dual-axis linkage assembly 21 is disposed above the processing surface 13, and the punching gun 22 is disposed on the dual-axis linkage assembly 21. The dual-axis linkage assembly 21 is used to drive the punching gun 22 to move in the X direction and the Z direction. The punching gun 22 is used to perform punching treatment on the surface of the aluminum single panel. In this example, the conveying direction of the aluminum single panel, that is, the direction from the feed end 11 to the discharge end 12, is the Y direction, while the X direction is the direction that spans the conveying device 10, and the Z direction is the direction that is perpendicular to the processing surface 13.

[0032] Specifically, the dual-axis linkage mechanism includes an X-axis moving mechanism 211 and a Z-axis moving mechanism 212. The X-axis moving mechanism 211 is mounted above the processing surface 13 and perpendicular to the line connecting the feed end 11 and the discharge end 12. The Z-axis moving mechanism 212 is slidably mounted on the X-axis moving mechanism 211, and the punch 22 is fixedly mounted on the Z-axis moving mechanism 212.

[0033] The X-axis moving mechanism 211 can be composed of a slide rail and a drag chain. The Z-axis moving mechanism 212 can be set on the slide rail and driven by gears and a rack set on the X-axis moving mechanism 211. The Z-axis moving mechanism 212 can move in the Z-axis direction by a cylinder. Since the punching accuracy is mainly reflected in the position of the aluminum single plate on the XY axis surface, the up and down movement in the Z-axis direction can be achieved by a cylinder.

[0034] Furthermore, there are two Z-axis moving mechanisms 212, both of which are slidably engaged with the X-axis moving mechanism 211, so that the opposite sides of the aluminum panel can be punched in a mirror or asymmetrical manner through the two Z-axis moving mechanisms 212.

[0035] The X-axis moving mechanism 211 is provided with a limit switch 213 and a limit plate 214 at both ends to limit the travel of the Z-axis moving mechanism 212; and a baffle 215 is provided between the two Z-axis moving mechanisms 212 to limit the travel of the two Z-axis moving mechanisms 212 and avoid collision and interference between the two Z-axis moving mechanisms 212.

[0036] The aluminum single-panel integrated forming processing line of the present invention also includes a bending mechanism 30 placed above the processing surface 13. The bending mechanism 30 includes two bending drive members 31 and two bending members 32 respectively disposed above the processing surface 13. The bending drive members 31 can drive the bending members 32 to reciprocate in the direction of approaching and moving away from the processing surface 13. In this example, the bending drive members 31 can also drive the bending members 32 to reciprocate in the X direction. The conveying device 10 is located on the processing surface 13 at the position of the bending mechanism 30, and forms a clearance space corresponding to the bending members 32 to avoid interference between the bending members 32 and the conveying device 10 during the bending process.

[0037] Furthermore, the bending drive component 31 includes a bending drive guide rail 311, a bending cylinder 312, and a slider that cooperates with the bending drive guide rail 311. The bending drive guide rail 311 is mounted above the processing surface 13 by a gantry structure bracket. The bending cylinder 312 is fixed to the slider so that the bending cylinder 312 slides back and forth along the length direction of the bending drive guide rail 311 via the slider, while the bending drive guide rail 311 is arranged along the X direction. The piston rod of the bending cylinder 312 is fixedly connected to the bending component 32. The piston rod of the bending cylinder 312 is perpendicular to the processing surface 13.

[0038] The bending drive guide rail 311 is also provided with multiple limit sensors 313 arranged along its length. By setting the limit sensors 313, the bending part 32 can be positioned and stopped at different positions in the X-axis direction to meet the bending position requirements of different aluminum panels. The bending drive guide rail 311 is provided with limit blocks 314 at opposite ends for blocking and limiting the slider.

[0039] The aforementioned punching mechanism 20 is located on the side of the processing surface 13 that is relatively close to the feeding end 11, and the bending mechanism 30 is located on the side of the processing surface 13 that is relatively close to the discharging end 12. After the aluminum single-panel sheet enters the conveying device 10, the surface of the sheet can be punched first, and then bent and positioned to avoid the situation where the bending part needs to be punched but cannot be punched after bending.

[0040] Furthermore, welding robots 40 are respectively installed on opposite sides of the processing surface 13. Side plate pushing devices 50 are respectively installed between the two welding robots 40 and the opposite sides of the processing surface 13. The side plate pushing devices 50 store multiple side plates and are used to push the side plates onto the processing surface 13. The welding robots 40 then weld the aluminum single panel body and the side plates, making the aluminum single panel structure more diverse and meeting the requirement of one-piece molding and output from the discharge end 12.

[0041] like Figure 7As shown, the side plate pushing device 50 includes a base 51. A fixed platform 52 is provided on the side of the base 51 away from the processing surface 13. An electric push rod 53 is installed on the fixed platform 52, which can reciprocate in the direction of approaching and moving away from the processing surface 13. The electric push rod 53 has a piston rod. A placement plate 54 for supporting the side plates is provided on the base 51. Limiting posts 55 are provided on opposite sides of the placement plate 54. A lifting device is provided between the placement plate 54 and the base 51. Multiple side plates can be stacked on the placement plate 54. The lifting device is used to drive the placement plate 54 to move away from or towards the base 51 in the vertical direction, so that the side plate at the top of the placement plate 54 is kept on the same horizontal plane as the electric push rod 53, so that the electric push rod 53 can push the topmost side plate onto the processing surface 13.

[0042] In this example, the conveying device 10 is equipped with positioning mechanisms at the corresponding workstations of the punching mechanism 20, bending mechanism 30, and welding robot 40. These mechanisms are used to clamp and position the aluminum single plate during the punching, bending, and welding processes to prevent displacement of the aluminum single plate from affecting the processing accuracy. This type of positioning mechanism is a common practice in the field of sheet metal processing and will not be described in detail here.

[0043] To achieve a one-time forming effect, the aluminum single-panel integrated forming processing line also includes a cutting mechanism 60. The cutting mechanism 60 is located outside the conveying device 10 and is connected to the feeding end 11. The cutting mechanism 60 includes an uncoiling machine 61, a leveling machine 62, and a cutting mechanism 63. An aluminum coil is installed on the cutting machine, and the coiled aluminum material can be placed on the aluminum coil. The leveling machine 62 is equipped with a leveling platform 621 and a leveling pressure roller 622, forming a gap between the leveling platform 621 and the leveling pressure roller 622. There is a leveling gap. The leveling machine 62 is located between the uncoiler 61 and the cutting mechanism 63. The cutting mechanism 63 is located outside the feed end 11 and is connected to the feed end 11. When the uncoiler 61 unwinds, the aluminum roll rotates and unwinds. The aluminum will enter the leveling gap between the leveling pressure roller 622 and the leveling platform 621. The leveling pressure roller 622 can level the aluminum and provide a certain traction force to the aluminum, reducing the burden on the aluminum roll. Finally, the leveled aluminum will be sent to the conveying device 10 for processing.

[0044] like Figure 6As shown, in order to cut aluminum materials into aluminum panels of the required dimensions, the cutting mechanism 63 includes a cutting frame 631, a conveyor belt 632, and a cutting mechanism 633 for cutting materials. The conveyor belt 632 is installed on the cutting frame 631 to carry the aluminum panels and transport them to the feeding end 11. The cutting mechanism 633 includes an upper pressure plate 6331 and a cutting drive mechanism 6332. The upper pressure plate 6331 is positioned above the conveyor belt 632. The cutting drive mechanism 6332 drives the upper pressure plate 6331 to move it up and down along the height of the frame. The upper pressure plate 6331 is equipped with a pressure knife. The cutting drive mechanism 6332 can achieve the reciprocating cutting effect through a cam mechanism. By calculating the conveying speed of the aluminum material and adjusting the speed of the cam mechanism according to the size of the aluminum panel, the cutting length of the aluminum panel can be made to match the length of the aluminum panel.

[0045] In order to improve the forming accuracy of the sheet metal, a measuring mechanism 70 is also provided between the leveling machine 62 and the cutting mechanism 63. In this example, the measuring mechanism 70 is located between the leveling machine 62 and the cutting mechanism 63.

[0046] The measuring mechanism 70 includes a measuring frame 71, on which two opposing measuring rollers 72 are mounted. Elastic components 73 are connected between the two measuring rollers 72. The ends of the two elastic components 73 that are far apart from each other are connected to the measuring frame 71, while the ends of the two elastic components 73 that are close to each other abut against the measuring rollers 72, so that the two measuring rollers 72 collide with each other. A measuring gap is formed between the measuring rollers 72 for the aluminum sheet to pass through. A displacement sensor is installed between the measuring rollers 72 and the measuring frame 71. When the aluminum material passes through the measuring gap, the sheet will apply a resisting force to the two measuring rollers 72, causing the two measuring rollers 72 to displace in a direction far apart from each other. The displacement sensor can calculate the thickness of the aluminum material. An encoder is installed on the measuring rollers 72. The rotation of the encoder can calculate the length of the aluminum material, thereby controlling the cutting speed of the cutting mechanism 633 in real time.

[0047] like Figure 8 As shown, the aluminum single-panel integrated forming processing line also includes a panel cleaning device 80, which is located outside the conveying device 10 and connected to the discharge end 12. The panel cleaning device 80 includes a cleaning table 81, a cleaning roller 82, and a cleaning roller device 83 connected to the discharge end 12. The surface of the cleaning table 81 is provided with multiple suction cups 811, and the cleaning table 81 is provided with a vacuuming device connected to the suction cups 811. The cleaning roller 82 and the cleaning roller device 83 are both installed on the upper part of the cleaning table 81 and can reciprocate in the direction of approaching and moving away from the surface of the cleaning table 81, so that the formed aluminum single panels can be cleaned. In order to meet the needs of aluminum single panels of different sizes, the cleaning table 81 in this example can be raised and lowered.

[0048] In this example, according to process requirements, weld grinding, surface grinding and spraying mechanisms can also be installed on the conveyor device 10 to achieve the effect of one-time processing of aluminum single panels, thereby improving the production efficiency of aluminum single panels and reducing the space occupancy rate.

[0049] The above embodiments are merely preferred embodiments of the present invention and should not be construed as limiting the scope of protection of the present invention. Any non-substantial changes and substitutions made by those skilled in the art based on the present invention shall fall within the scope of protection claimed by the present invention.

Claims

1. An aluminum veneer integrated molding processing line, characterized by include: A conveying device, one end of which is a feeding end and the other end of which is a discharging end, is provided with a plurality of parallel drive rollers arranged side by side, and the plurality of drive rollers have processing surfaces for supporting aluminum panels. The punching mechanism is provided on the conveying device, and the punching mechanism includes a dual-axis linkage assembly and a punching gun; the dual-axis linkage assembly is provided above the processing surface, and the punching gun is provided on the dual-axis linkage assembly. A bending mechanism is placed above the processing surface. The bending mechanism includes two bending drive members and two bending members respectively disposed above the processing surface. The bending drive members can drive the bending members to reciprocate in the direction of approaching and moving away from the processing surface. The punching mechanism is located on the side of the processing surface that is relatively close to the feed end, and the bending mechanism is located on the side of the processing surface that is relatively close to the discharge end. Welding robots are respectively installed on opposite sides of the processing surface, and side plate pushing devices are respectively installed between the two welding robots and the opposite sides of the processing surface. The aluminum single-panel integrated forming processing line also includes a cutting mechanism, which is located outside the conveying device and connected to the feeding end; The cutting mechanism includes an uncoiler, a leveler, and a cutting mechanism. An aluminum coil is installed on the uncoiler. The leveler is equipped with a leveling platform and a leveling roller. A leveling gap is formed between the leveling platform and the leveling roller. The leveler is located between the uncoiler and the cutting mechanism. The cutting mechanism is located outside the feeding end and is connected to the feeding end. A measuring mechanism is also provided between the leveling machine and the cutting mechanism; The measuring mechanism includes a measuring frame with two opposing measuring rollers. An elastic component is connected between the two measuring rollers. The ends of the two elastic components that are far apart from each other are connected to the measuring frame, and the ends of the two elastic components that are close to each other abut against the measuring rollers so that the two measuring rollers collide with each other. A measuring gap is formed between the two measuring rollers for the aluminum single panel to pass through. A displacement sensor is provided between the measuring rollers and the measuring frame. An encoder is installed on the measuring roller; The side plate pushing device includes a base, a fixed platform is provided on the side of the base away from the processing surface, an electric push rod is installed on the fixed platform that can reciprocate in the direction of approaching and moving away from the processing surface, a placement plate is provided on the base, and limit posts are provided on opposite sides of the placement plate. The dual-axis linkage mechanism includes an X-axis moving mechanism and a Z-axis moving mechanism; The X-axis moving mechanism is mounted above the processing surface and perpendicular to the line connecting the feed end and the discharge end. The Z-axis moving mechanism is slidably mounted on the X-axis moving mechanism, and the punch is fixedly mounted on the Z-axis moving mechanism. The bending drive component includes a bending drive guide rail, a bending cylinder, and a slider that cooperates with the bending drive guide rail. The bending drive guide rail is mounted above the machining surface, and the bending cylinder is fixed to the slider so that the bending cylinder slides back and forth along the length direction of the bending drive guide rail via the slider; the piston rod of the bending cylinder is fixedly connected to the bending part; the piston rod of the bending cylinder is perpendicular to the machining surface.

2. The integrated processing line for aluminum sheet according to claim 1, wherein: The cutting mechanism includes a cutting frame, a conveyor belt, and a cutting mechanism for cutting materials. The conveyor belt is installed on the cutting frame to carry aluminum panels and transport them to the feeding end. The cutting mechanism includes an upper pressure plate and a cutting drive mechanism. The upper pressure plate is disposed above the conveyor belt, and the cutting drive mechanism is connected to the upper pressure plate to drive the upper pressure plate to move up and down reciprocally along the height direction of the frame.

3. The integrated processing line for aluminum sheet according to claim 1, wherein: The aluminum single-panel integrated forming processing line also includes a panel cleaning device, which is located outside the conveying device and connected to the discharge end. The panel cleaning device includes a cleaning table, a cleaning roller, and a cleaning roller device that are connected to the discharge end; the surface of the cleaning table is provided with multiple suction cups, and the cleaning table is provided with a vacuuming device connected to the suction cups; the cleaning roller and the cleaning roller device are both installed on the upper part of the cleaning table and can reciprocate in the direction of approaching and moving away from the surface of the cleaning table.

4. The integrated processing line for aluminum sheet according to claim 1, wherein: There are two Z-axis moving mechanisms, and both Z-axis moving mechanisms are slidably engaged with the X-axis moving mechanism. The X-axis moving mechanism is provided with a limit switch and a limit plate at both ends to limit the travel of the Z-axis moving mechanism; a baffle is also provided between the two Z-axis moving mechanisms to limit the travel of the two Z-axis moving mechanisms and avoid collision and interference between the two Z-axis moving mechanisms.

5. The integrated processing line for aluminum sheet according to claim 1, wherein: The bending drive rail is also provided with a plurality of limit sensors arranged along its length; the opposite ends of the bending drive rail are respectively provided with limit blocks for blocking and limiting the slider.

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