Anti-wrinkle assembly for aluminum foil production

The anti-wrinkle component, which uses multi-stage gear chain transmission and synchronous control, solves the wrinkling problem in aluminum foil production, achieving smooth aluminum foil surface and efficient production, thus improving product quality and equipment performance.

CN224394228UActive Publication Date: 2026-06-23HENAN SONGSHAN ALUMINUM CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
HENAN SONGSHAN ALUMINUM CO LTD
Filing Date
2025-08-28
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Existing aluminum foil production equipment is prone to wrinkles during tension control, guiding, and slitting processes, leading to defects in the appearance of finished products and a decrease in barrier properties. Furthermore, it lacks effective drying equipment linkage and dust removal functions.

Method used

Employing a multi-stage gear chain drive system, combined with front and rear tension rollers, a fan, and anti-wrinkle rollers, it achieves precise power distribution and synchronization. directional airflow eliminates static electricity and foreign matter, and in conjunction with a cleaning brush, it performs online cleaning to ensure a smooth aluminum foil surface and anti-wrinkle effect.

Benefits of technology

It effectively prevents aluminum foil from wrinkling during the production process, improves surface quality and product qualification rate, enhances equipment efficiency and stability, and reduces the impact of dust and foreign matter.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model discloses an anti -wrinkle subassembly for aluminum foil production relates to aluminum foil production technical field, including work table, the outside fixed mounting of work table has the support frame, the one side bolt mounting of support frame has rotary motor no. 1, the output of rotary motor no. 1 is from the outside of support frame and penetrates the connection pinion no. 1, the outside of pinion no. 1 is engaged with the spur gear no. 1, the one side fixed mounting of spur gear no. 1 has the pivot no. 1, the one end of pivot no. 1 is from the outside of square block board no. 1 and penetrates the connection a plurality of spur gear no. 3, the one end of pivot no. 1 is from the outside of spur gear no. 3 and penetrates the connection spur gear no. 4, the outside of spur gear no. 4 is engaged with pinion no. 2, through adopting multistage gear chain drive, the step -by -step drive mode of pinion no. 1 to spur gear no. 6, realizes the accurate distribution and synchronization of power, makes fan and anti -wrinkle roller etc. Core components synchronous operation, avoids the wrinkle that produces because of speed difference.
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Description

Technical Field

[0001] This utility model relates to the field of aluminum foil production technology, and in particular to an anti-wrinkle component for aluminum foil production. Background Technology

[0002] Aluminum foil, due to its excellent barrier properties and flexibility, is widely used in food, pharmaceutical, and industrial packaging. The production process typically involves continuous rolling and slitting, where aluminum coils, ranging from tens to hundreds of micrometers in thickness, are rolled thinner using multi-stage rolling mills, followed by cutting and slitting. During this process, the high flexibility and extremely thinness of aluminum foil make it highly susceptible to wrinkles during tension control, guiding, and slitting. Once wrinkles form, they not only lead to defects in the finished product's appearance but also compromise the material's barrier properties, severely impacting product quality and market competitiveness. Furthermore, existing aluminum foil production equipment has a relatively simple structure, low-efficiency drying equipment, lacks a linkage mechanism, and lacks dust removal functionality. Utility Model Content

[0003] To address the shortcomings of existing technologies, this utility model provides an anti-wrinkle component for aluminum foil production, which solves the problems mentioned in the background.

[0004] To achieve the above objectives, this utility model provides the following technical solution: an anti-wrinkle component for aluminum foil production, comprising a workbench, a support frame fixedly mounted on the outer side of the workbench, a rotary motor I bolted to one side of the support frame, a pinion I penetrating through the outer side of the rotary motor I and connected to the output end of the rotary motor I, a large gear I meshing with the outer side of the pinion I, a rotating shaft I fixedly mounted on one side of the large gear I, a plurality of large gears III penetrating through the outer side of a block plate I at one end of the rotating shaft I, a large gear IV penetrating through the outer side of the large gears III at one end of the rotating shaft I, a pinion II meshing with the outer side of the large gear IV, a rotating shaft II welded to one side of the pinion II, and a rotating shaft II penetrating through the outer side of the block plate II at one end of the rotating shaft II. Several large gears (5) are connected through the outer side. One end of the rotating shaft (2) is connected to a small gear (3) through the outer side of the large gears (5). A large gear (6) meshes with the outer side of the small gear (3). A rotating shaft (3) is welded to one side of the large gear (6). One end of the rotating shaft (3) is connected to several large gears (6) through the outer side of the block plate (3). Another rotating shaft (3) is connected to the rotating groove of another block plate (3) through the outer side of the large gears (6). Small gears (4) mesh with the outer sides of several large gears (3) and large gears (5). A rotating shaft (4) is welded to one side of several small gears (4). A fan is connected through the outer side of several rotating shafts (4). Another filter support plate is connected through the outer side of several rotating shafts (4).

[0005] As a further technical solution of this utility model, the top surface of the workbench is bolted with a rectangular frame, the outer side of the rectangular frame is bolted to block plate one, block plate two and block plate three, and baffles are bolted between several blocks plate one, block plate two and block plate three, ventilation holes are opened in the middle of several baffles, and filter screens are bolted to the inner sidewalls of several ventilation holes.

[0006] As a further technical solution of this utility model, the outer side of the small gear 1 meshes with two linkage gear 1, and a rotating shaft 5 is welded to one side of each of the two linkage gear 1. One end of each of the two rotating shafts 5 passes through and connects to linkage gear 2 from the outer side of block plate 4. The outer side of each of the two linkage gear 2 meshes with large gear 7. A rotating shaft 6 is welded to one side of each of the two large gear 7. One end of each of the two rotating shafts 6 passes through and connects to another two large gear 7 from the outer side of block plate 5. One end of each of the two rotating shafts 6 passes through and connects to another block plate 5 from the outer side of the other two large gear 7.

[0007] As a further technical solution of this utility model, the outer sides of the two large gears are meshed with transmission gears, and one side of each of the two transmission gears is welded with a transmission shaft. One end of each of the two transmission shafts passes through the outer side of the support plate and connects to the anti-wrinkle roller. The distance between the two anti-wrinkle rollers is the same as the thickness of the aluminum foil. The top surface of the workbench is bolted to the support plate.

[0008] As a further technical solution of this utility model, the top surface of the workbench is bolted to two support plates II, one of which is bolted to a rotary motor II. The output end of the rotary motor II is connected to a tension roller I through the outside of the support plate II. The tension roller I is coated with high-elasticity polyurethane to reduce the risk of wrinkles caused by the rebound of aluminum foil. The shaft ends of the tension roller I are all connected to the support plate II through lubricated needle roller bearings to reduce friction and extend service life.

[0009] As a further technical solution of this utility model, one side of one of the block plate five and the two block plates four are bolted to the side of the workbench.

[0010] As a further technical solution of this utility model, a cleaning plate is bolted to one side of both the support plate three and the support plate two, and the bottom surface of the cleaning plate is used to connect a cleaning brush by bolts.

[0011] This utility model provides an anti-wrinkle component for aluminum foil production, which has the following advantages compared with the prior art:

[0012] Beneficial effects:

[0013] 1. This design provides an anti-wrinkle component for aluminum foil production. By employing a multi-stage gear chain drive with a graded transmission mode from pinion one to gear six, precise power distribution and synchronization are achieved, enabling core components such as the fan and anti-wrinkle roller to operate synchronously and avoiding wrinkles caused by speed differences.

[0014] 2. The anti-wrinkle component for aluminum foil production designed in this paper provides double tension force to the aluminum foil through the coordinated action of the front tension roller 1 and the rear tension roller 2, ensuring uniform tension distribution and suppressing local relaxation and wrinkles caused by springback or tension fluctuations.

[0015] 3. This design provides an anti-wrinkle component for aluminum foil production. Multiple fans blow airflow filtered through a filter support plate onto the aluminum foil surface in a directional manner, effectively eliminating static electricity and removing tiny particles, preventing initial wrinkles caused by foreign objects, and improving the surface quality of the material.

[0016] 4. This design provides an anti-wrinkle component for aluminum foil production. By precisely matching the gap between the anti-wrinkle rollers with the thickness of the aluminum foil, and with the aid of a wear-resistant coating, it can flatten and correct wrinkles without damaging the surface of the aluminum foil, thereby improving the final product qualification rate.

[0017] 5. This design provides an anti-wrinkle component for aluminum foil production. By combining a cleaning plate with a replaceable cleaning brush, it enables online cleaning of the equipment, prevents the accumulation of dust and aluminum shavings, and maintains a long-term stable anti-wrinkle effect. Attached Figure Description

[0018] Figure 1 A schematic diagram of the overall structure of an anti-wrinkle component for aluminum foil production;

[0019] Figure 2 A schematic diagram of the cross-sectional elevation of a fan for an anti-wrinkle component used in aluminum foil production;

[0020] Figure 3 This is a side sectional elevation view of an anti-wrinkle component for aluminum foil production.

[0021] In the diagram: 1. Workbench; 2. Support frame; 3. Rotary motor one; 4. Small gear one; 41. Small gear two; 42. Small gear three; 5. Large gear one; 6. Rotating shaft one; 61. Rotating shaft two; 63. Rotating shaft three; 64. Rotating shaft four; 65. Rotating shaft five; 66. Rotating shaft six; 7. Fan; 8. Rectangular frame; 9. Linkage gear one; 10. Linkage gear two; 11. Large gear seven; 12. Transmission gear; 13. Anti-wrinkle roller; 14. Rotary motor two; 15. Tensioning roller one; 16. Rotary motor three; 17. Tensioning roller two. Detailed Implementation

[0022] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present utility model. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. All other embodiments obtained by those skilled in the art based on the embodiments of the present utility model without creative effort are within the protection scope of the present utility model.

[0023] Please see Figure 1-3 This utility model provides a technical solution for an anti-wrinkle component used in aluminum foil production:

[0024] like Figure 2As shown, the machine includes a workbench 1, which is welded from rectangular steel plates and has an electrostatic spray coating. Mounting holes are provided on the top surface for bolting support frames 2, 2, and 3, providing a mounting base for the entire machine, ensuring the overall rigidity and positioning accuracy of the components, and withstanding the forces generated during tensioning and pressing. Support frames 2 are fixedly installed on the outer side of the workbench 1. Support frames 2 are U-shaped steel plates bent into a frame, with reinforcing ribs connecting the four corners. A hole is opened on one side for bolting rotary motor 3. The bolts are aligned with the holes on the top of the workbench 1 to ensure the positional accuracy between the transmission components and the tensioning components. This ensures the support of rotary motor 3 and the multi-stage gear mechanism, providing robust support for the transmission system. Rotary motor 3, model YVF2-112M-4, with a power of 0.75kW, a speed of 1440rpm, and an output shaft diameter of Φ19mm, is bolted to one side of support frame 2. The base is bolted to the support frame 2, serving as the main power source to provide stable power to the pinion 4. The output end of the rotary motor 3 passes through and connects to the pinion 4 from the outside of the support frame 2. The pinion 4 is a precision-cast steel part with a module m=1.5 and a number of teeth Z=20, and is fixed to the output shaft end of the rotary motor 3. The large gear 5 has a module m=1.5 and a number of teeth Z=60. It is heat-treated and uses key connection and interference fit to connect the pinion 4 to the motor shaft and the large gear 5 to the rotating shaft 6.The gear meshing, with a 4mm meshing clearance and grease lubrication, completes the first-stage reduction and torque amplification, providing suitable speed and torque for the subsequent transmission. A large gear 5 meshes with the outer side of pinion 4. A rotating shaft 6 is fixedly mounted on one side of the large gear 5. One end of the rotating shaft 6 passes through the outer side of the square plate 1, connecting several large gears 3. Another end of the rotating shaft 6 passes through the outer side of the large gears 3, connecting a large gear 4. The rotating shaft 6 is made of 45# steel, Φ25mm, and has grooves at both ends for mounting large gears 3 (Z=80 teeth) and large gears 4 (Z=40 teeth). The gears are fixed by keyways. The rotating shaft 6 passes through the square plate 1, which has Φ30mm bearing holes for deep groove ball bearings to ensure smooth rotation. Power is distributed to a multi-stage gear chain, and the rotational power is transmitted to pinion 2 41. Pinion 2 41 meshes with the outer side of large gear 4. A rotating shaft 2 61 is welded to one side of pinion 2 41. One end of rotating shaft 2 61 passes through the outer side of block plate 2 and connects to several large gears 5. The other end of rotating shaft 2 61 passes through the outer side of large gears 5 and connects to pinion 3 42. Pinion 2 41 (Z=20) is welded to the end of rotating shaft 2 61. Rotating shaft 2 61 (Φ20mm) passes through block plate 2 and is supported by bearings. Large gear 5 (Z=60) is assembled in the middle of rotating shaft 2 61 and connected by a key. Pinion 3 42 (Z=16) is mounted on the other end of rotating shaft 2 61. Pinion 3 42 meshes with large gear 6 (Z=48), which is welded to rotating shaft 3 63, forming a... The second and third stage transmissions further adjust the speed and transmit power to the rotating shaft 63. A large gear 6 meshes with the outer side of the small gear 42. A rotating shaft 63 is welded to one side of the large gear 6. One end of the rotating shaft 63 passes through the outer side of the square plate 3, connecting several large gears 6. Another end of the rotating shaft 63 passes through the outer side of the large gears 6, connecting to the rotating groove of another square plate 3. The rotating shaft 63 (Φ20mm) passes through the square plate 3 and has a second set of large gears 6 on its outer side, achieving power branching. The square plate 3 is a 12mm thick steel plate, bolted to the side of the workbench, distributing power to the peripheral linkage small gear 4, driving the fan 7. Several large gears 3 and the outer side of the large gear 5 are all meshed with small gears 4. Several small gears... One side of each of the four is welded with a rotating shaft 64. One end of each of the rotating shafts 64 passes through the outside of the filter support plate and is connected to a fan 7. One end of each of the rotating shafts 64 passes through the outside of the fan 7 and is connected to another filter support plate. The small gear 4 (Z=24) meshes with the large gears 3 / 5 / 6. One end of the rotating shaft 64 (Φ15mm) is welded to the small gear 4 through an interference fit, and the other end is installed in the center of the filter support plate through a bearing. The impeller of the fan 7 has a diameter of Φ100mm and is fixed on the outside of the rotating shaft 64. The filter support plate and the support frame 2 are connected by bolts, and a 10mm gap is reserved between the filter and the fan 7. The fan 7 rotates at high speed to generate directional airflow, which blows the aluminum foil after being purified by the filter, removing static electricity and particles and smoothing the surface wrinkles.

[0025] like Figure 3 As shown, a rectangular frame 8 is bolted to the top surface of the workbench 1. The outer side of the rectangular frame 8 is bolted to square plate one, square plate two, and square plate three. Several square plates one, two, and three are bolted to each other with baffles. Ventilation holes are opened in the middle of several baffles. Filter screens are bolted to the inner walls of several ventilation holes. The rectangular frame 8 is welded from angle steel and bolted to the top surface of the workbench 1. Square plates one, two, and three are bolted to the rectangular frame 8. Baffles are installed between the square plates. Ventilation holes with a diameter of Φ50mm are opened in the center of the baffles. The filter screen is a stainless steel perforated plate bolted to the inner side of the baffles, forming a multi-stage air duct to filter and distribute the airflow in sections, preventing particles from clogging the inlet of the fan 7.

[0026] like Figure 3 As shown, the outer side of the small gear 4 meshes with two linkage gears 9. One side of each linkage gear 9 is welded with a rotating shaft 65. One end of each rotating shaft 65 passes through the outer side of the block plate 4 and connects to linkage gear 10. The outer side of each linkage gear 10 meshes with a large gear 11. One side of each large gear 11 is welded with a rotating shaft 66. One end of each rotating shaft 66 passes through the outer side of the block plate 5 and connects to another large gear 11. One end of each rotating shaft 66 passes through the outer side of the other two large gears 11 and connects to another block plate 5.

[0027] like Figure 3 As shown, the outer sides of the two large gears 7 11 are meshed with transmission gears 12. A transmission shaft is welded to one side of each of the two transmission gears 12. One end of each transmission shaft passes through the outer side of the support plate 1 and connects to the anti-wrinkle roller 13. The distance between the two anti-wrinkle rollers 13 is the same as the thickness of the aluminum foil. The top surface of the workbench 1 is bolted to the support plate 1. The side of the small gear 4 meshes with two sets of linkage gears 9 (Z=18). The linkage gears 9 are welded with a rotating shaft 5 65 (Φ12mm), which passes through the square plate 4. Linkage gear 2 10 (Z=36) is assembled at the other end of the rotating shaft 5 65. Linkage gear 2 meshes with large gear 7 11 (Z=72). The large gear 711 is fixed to the rotating shaft 66 (Φ20mm) by welding; the rotating shaft 66 passes through the square plate 5 and is connected to another set of large gears 711 at the end; the large gears 711 mesh with the transmission gear 12 (Z=24), the transmission gear is welded to the transmission shaft (Φ15mm), and the other end of the transmission shaft is equipped with an anti-wrinkle roller 13 through a bearing. The anti-wrinkle roller 13 has a diameter of Φ30mm and its length is customized according to the width of the aluminum foil. The surface is sprayed with a wear-resistant fluorine coating. The gap between the two rollers is adjusted by shims with an accuracy of ±0.05mm to match the thickness of the aluminum foil. The linkage transmission ensures that multiple sets of anti-wrinkle rollers 13 rotate synchronously at the same speed, pressing the aluminum foil to eliminate wrinkles in the middle and late stages.

[0028] like Figure 1As shown, the top surface of the workbench 1 is bolted to two support plates 2. One side of one of the support plates 2 is bolted to a rotary motor 2 14. The output end of the rotary motor 2 14 passes through the outside of the support plate 2 and is connected to a tension roller 15. The tension roller 15 is coated with high-elasticity polyurethane to reduce the risk of wrinkles caused by the rebound of aluminum foil. The shaft ends of the tension roller 15 are all connected to the support plate 2 through lubricated needle roller bearings to reduce friction and extend service life.

[0029] like Figure 1 As shown, the top surface of the workbench 1 is bolted to two support plates 3. One of the support plates 3 has a rotary motor 3 16 bolted to its outer side. The output end of the rotary motor 3 16 passes through the outer side of the support plate 3 and is connected to a tension roller 2 17. The shaft ends of the tension roller 2 17 are all connected to the support plate 3 through lubricated needle roller bearings to reduce friction and extend service life.

[0030] like Figure 1 As shown, one side of one of the square plate five and the two square plates four are bolted to the side of the workbench 1.

[0031] like Figure 1 As shown, a cleaning plate is bolted to one side of both support plate three and support plate two. The bottom surface of the cleaning plate is used to connect a cleaning brush via bolts. The cleaning plate is a stainless steel bent part, which is bolted to the side of support plate two and support plate three. The cleaning brush is a nylon brush that can be quickly disassembled and replaced. Together with tension roller one 15, tension roller two 17 and anti-wrinkle roller 13, it cleans the residual powder and aluminum shavings on the surface, keeps the roller surface and air duct clean, and ensures stable anti-wrinkle effect.

[0032] The working principle of this utility model is as follows: First, the output end of the drive rotary motor 3 drives the small gear 4, which in turn drives the large gear 5 and the rotating shaft 6. Several large gears 3 and 4 are then driven, further driving the small gear 2 41 and the rotating shaft 2 61. This further drives several large gears 5 and the small gear 3 42, and then the large gear 6 and the rotating shaft 3 63. Several large gears 6 are then driven, and several large gears 3, 3, and 5 drive the small gear 4 and the rotating shaft 4 64, further causing the fan 7 to rotate. Because the filter screen and support frame are fixed in the middle of the filter support plate by bolts, the air from the fan 7 blows through the filter screen holes onto the aluminum foil. Secondly, the small gear 4 rotates... During the process, the two side linkage gears 1-9 and rotating shaft 5-65 rotate simultaneously, further driving linkage gear 2-10. Linkage gear 2-10 drives large gear 7-11 and rotating shaft 6-66, further driving the two rotating shafts 6-66 on rotating shaft 6-66, further driving the other two large gears 7-11 on rotating shaft 6-66. Large gears 7-11 drive transmission gear 12 and transmission shaft, further rotating the anti-wrinkle roller 13. Finally, the output end of rotary motor 2-14 rotates to rotate tension roller 1-15, and the output end of rotary motor 3-16 rotates to rotate tension roller 2-17. During the movement of the aluminum foil, the bottom surface of the cleaning plate contacts the cleaning brush, which can clean the dust on the surface of the aluminum foil and prevent large dust particles from affecting the flatness of the aluminum foil.

[0033] I. Motor Drive and Primary Tensioning: Rotary motor 2 (14) drives tension roller 1 (15), and rotary motor 3 (16) drives tension roller 2 (17), applying flexible tension to the aluminum foil entering the assembly to ensure stable tension during subsequent transmission. Rotary motor 1 (3) outputs power to pinion 1 (4), large gear 1 (5), shaft 1 (6), large gear 3 / 4, pinion 2 (41), shaft 2 (61), large gear 5, pinion 3 (42), large gear 6, and shaft 3 (63), forming a multi-stage gear chain to provide primary power distribution for fan 7 and anti-wrinkle roller 13. II. Directional Air Blowing and Multi-Stage Pressing: In the multi-stage gear chain, the outer sides of large gears 3, 5, and 6 mesh with pinion 4. Shaft 4 (64) is driven by pinion 4, causing fan 7 to rotate. Fan 7 blows out uniform airflow through the filter support plate, directionally blowing on the aluminum foil surface to eliminate static electricity and microparticles, smoothing out initial wrinkles. Pinion 1 (4) The meshing linkage gear 19—rotating shaft 5 65—linkage gear 2 10—large gear 7 11—rotating shaft 66 drives transmission gear 12, and the transmission shaft drives anti-wrinkle roller 13. The gap between the two anti-wrinkle rollers 13 is set to the aluminum foil thickness to accurately press and correct the aluminum foil; III. Real-time maintenance and synchronous control; All tension rollers 15, 17, fan 7 and anti-wrinkle roller 13 shafts are supported by lubricated needle roller bearings to ensure low friction, low noise and long service life; The cleaning plates on the outside of support plates 2 and 3, together with cleaning brushes, regularly remove dust and aluminum chips from the roller surface and inside the air duct to keep the airflow smooth and the surface clean; The electrical control system can adjust the speed and tension torque of rotary motors 13, 24, and 36 in real time according to parameters such as aluminum foil thickness and production speed to achieve synchronous linkage of each level of transmission with blowing, pressing and cleaning, so that the components continuously and stably suppress wrinkle formation.

[0034] The above description is merely a preferred embodiment of this utility model. It should be noted that those skilled in the art can make various improvements and modifications without departing from the principles of this utility model, and these improvements and modifications should also be considered within the scope of protection of this utility model. Structures, devices, and operating methods not specifically described or explained in this utility model are implemented according to conventional methods in the art, unless otherwise specified or limited.

Claims

1. A crease-preventing assembly for aluminum foil production, characterized by, The system includes a workbench (1), a support frame (2) fixedly installed on the outside of the workbench (1), a rotary motor (3) bolted to one side of the support frame (2), a small gear (4) being connected through the outside of the support frame (2), a large gear (5) meshing with the outside of the small gear (4), a rotating shaft (6) fixedly installed on one side of the large gear (5), a number of large gears (3) being connected through the outside of the block plate (1) at one end of the rotating shaft (6), a large gear (4) being connected through the outside of the large gear (3) at one end of the rotating shaft (6), a small gear (41) meshing with the outside of the large gear (41), a rotating shaft (61) being welded to one side of the small gear (41), and a number of large gears (5) being connected through the outside of the block plate (2) at one end of the rotating shaft (61). One end of the rotating shaft 2 (61) passes through the outside of the large gear 5 and is connected to the small gear 3 (42). The small gear 3 (42) is meshed with the large gear 6 on the outside. The rotating shaft 3 (63) is welded to one side of the large gear 6. One end of the rotating shaft 3 (63) passes through the outside of the block plate 3 and is connected to several large gears 6. One end of the rotating shaft 3 (63) passes through the outside of the large gear 6 and is connected to the rotating groove of another block plate 3. The outer sides of several large gears 3 and large gear 5 are all meshed with small gears 4. The side of several small gears 4 is welded to one side of each of them. One end of each of the aforementioned four shafts (64) is connected to a fan (7) through the outside of the filter support plate, and one end of each of the aforementioned four shafts (64) is connected to another filter support plate through the outside of the fan (7).

2. The anti-wrinkling assembly for aluminum foil production according to claim 1, characterized in that, The top surface of the workbench (1) is bolted with a rectangular frame (8). The outer side of the rectangular frame (8) is bolted to square plate one, square plate two and square plate three. Several square plates one, square plate two and square plate three are bolted together with baffles. Several baffles are provided with ventilation holes in the middle. Several ventilation holes are bolted with filter screens on their inner sidewalls.

3. The anti-wrinkling assembly for aluminum foil production according to claim 1, characterized in that, The outer side of the small gear 1 (4) meshes with two linkage gear 1 (9). A rotating shaft 5 (65) is welded to one side of each of the two linkage gear 1 (9). One end of each of the two rotating shafts 5 (65) passes through the outer side of the block plate 4 and connects to linkage gear 2 (10). The outer side of each of the two linkage gears 2 (10) meshes with large gear 7 (11). A rotating shaft 6 (66) is welded to one side of each of the two large gears 7 (11). One end of each of the two rotating shafts 6 (66) passes through the outer side of the block plate 5 and connects to another large gear 7 (11). One end of each of the two rotating shafts 6 (66) passes through the outer side of the other two large gears 7 (11) and connects to another block plate 5.

4. The anti-wrinkling assembly for aluminum foil production according to claim 3, characterized in that, The outer sides of the two large gears (11) are meshed with transmission gears (12), and one side of each of the two transmission gears (12) is welded with a transmission shaft. One end of each of the two transmission shafts passes through the outer side of the support plate and is connected to the anti-wrinkle roller (13). The distance between the two anti-wrinkle rollers (13) is the same as the thickness of the aluminum foil. The top surface of the workbench (1) is bolted to the support plate.

5. The anti-wrinkle component for aluminum foil production according to claim 1, characterized in that, The top surface of the workbench (1) is bolted with two support plates 2. One side of one of the support plates 2 is bolted with a rotary motor 2 (14). The output end of the rotary motor 2 (14) is connected to a tension roller 1 (15) through the outside of the support plate 2. The tension roller 1 (15) is coated with high-elasticity polyurethane to reduce the risk of wrinkles caused by the rebound of aluminum foil. The shaft ends of the tension roller 1 (15) are all connected to the support plate 2 through lubricated needle roller bearings to reduce friction and extend service life.

6. The anti-wrinkle component for aluminum foil production according to claim 1, characterized in that, The top surface of the workbench (1) is bolted with two support plates (3). One of the support plates (3) is bolted with a rotary motor (3) (16) on its outer side. The output end of the rotary motor (3) (16) passes through the outer side of the support plate (3) and is connected to a tension roller (2) (17). The shaft ends of the tension roller (2) (17) are all connected to the support plate (3) through lubricated needle roller bearings to reduce friction and extend service life.

7. The anti-wrinkle component for aluminum foil production according to claim 1, characterized in that, One side of one of the block plate five and the two block plates four are bolted to the side of the workbench (1).

8. The anti-wrinkle component for aluminum foil production according to claim 1, characterized in that, One side of both support plate three and support plate two is bolted to a cleaning plate, and the bottom surface of the cleaning plate is used to connect a cleaning brush via bolts.