CN114775011B - Aluminum guide foil cut oxide film repair forming system and process - Google Patents

Abstract

The application discloses a system and a process for forming an aluminum guide foil cutting oxide film, and relates to the technical field of aluminum foil forming. The aluminum guide foil cutting opening oxidation film supplementing and forming system comprises a ring track, a formation groove and a movable seat, wherein the formation groove is formed in the periphery of the ring track, the movable seat is slidably connected with the ring track, an automatic clamp used for clamping guide foil is arranged on the movable seat, a rotating assembly used for driving the automatic clamp to rotate is arranged on the movable seat, electrolyte impregnated cotton blocks are arranged in the formation groove, and the electrolyte impregnated cotton blocks are arranged below the automatic clamp. The application not only can complete the supplement formation of the notch of the guide foil, but also can reduce the consumption of electrolyte, thereby being beneficial to saving the electrolyte.

Description

Aluminum guide foil cut oxide film repair forming system and process

Technical Field

The application relates to the technical field of aluminum foil repair formation, in particular to an aluminum guide foil cut oxide film repair formation system and process.

Background

The aluminum guide foil is an aluminum foil used to manufacture a capacitor in which both the cathode foil and the anode foil are aluminum guide foils. In the process of manufacturing the capacitor, the aluminum guide foil is firstly cut to prepare the foil with the required size specification. Because the surface of the cut opening of the cut foil is not covered with the oxide film, the cut foil needs to be subjected to repair forming, and the oxide film and the solid electrolyte layer are formed on the surface of the cut opening of the foil.

In the related art, a method for supplementing and forming aluminum foil is disclosed, wherein after aluminum foil is cut, the aluminum foil is put into electrolyte, the aluminum foil is supplemented and formed, and an oxide film is formed on the cut surface of the aluminum foil.

In view of the above-described related art, the inventors considered that in the course of performing the replenishment process, it is necessary to immerse the aluminum foil in the electrolyte, and the electrolyte adheres to the surface of the aluminum foil, which does not need to be replenishment, resulting in excessive consumption of the electrolyte.

Disclosure of Invention

In order to save electrolyte, the application provides a system and a process for forming an aluminum guide foil cutting oxide film.

In a first aspect, the present application provides a system for forming an oxide film on an aluminum guide foil cut by using the following technical scheme:

the utility model provides an aluminium guide foil cuts out incision oxide film and mends formation system, includes ring track, formation groove and removal seat, a plurality of formation groove is located the orbital week side of ring, a plurality of remove seat sliding connection and be in on the ring track, it is equipped with the automatic clamp that is used for the centre gripping guide foil to remove the seat, it is used for the drive to remove to install on the seat automatic clamp pivoted rotating assembly, be equipped with electrolyte flooding cotton piece in the formation groove, electrolyte flooding cotton piece is located automatic clamp below.

By adopting the technical scheme, the electrolyte impregnating cotton block is arranged in the formation tank, so that the electrolyte in the formation tank can be absorbed into the electrolyte impregnating cotton block. After the automatic clamp clamps the guide foil, the guide foil moves synchronously along with the moving seat, so that the notch on one side of the guide foil is abutted on the electrolyte impregnated cotton block, the moving block is operated to move along the ring track, the guide foil can slide on the electrolyte impregnated cotton block, and meanwhile, the notch of the guide foil is complemented by electrolyte. Then, the rotating assembly is operated to drive the automatic clamp and the guide foil to synchronously rotate, the notch on the other side of the guide foil is abutted against the electrolyte impregnated cotton block, and the notch on the other side of the guide foil is formed in a supplementing mode. Because the contact surface of the guide foil and the electrolyte is small, the compensation of the notch of the guide foil can be completed, the consumption of the electrolyte can be reduced, and the effect of saving the electrolyte is realized.

In a specific implementation manner, the formation groove comprises a groove body, a pushing plate, an air cylinder and a connecting rod, wherein the pushing plate is arranged in the groove body, the air cylinder is fixedly connected to the outer wall of the groove body, the connecting rod is fixedly connected to the telescopic end of the air cylinder, the connecting rod is fixedly connected with the pushing plate, and the electrolyte impregnated cotton block is fixed to the pushing plate.

By adopting the technical scheme, the tank body is used for containing electrolyte, so that the electrolyte-impregnated cotton block can absorb the electrolyte. When the electrolyte impregnated cotton block is located in the tank, the blocking of the movement of the guide foil can be avoided. When the guide foil moves to the position above the electrolyte impregnated cotton block, the air cylinder pushes the connecting rod and the push plate to move, so that the electrolyte impregnated cotton block can be pushed to be close to the guide foil, and the electrolyte on the electrolyte impregnated cotton block is contacted with the notch of the guide foil, so that the supplement formation is completed.

In a specific implementation mode, the movable seat comprises a movable box, a mounting plate and a driving piece for driving the movable box to move, a through groove is formed in the movable box, the ring rail penetrates through the through groove, the ring rail is in butt joint with the groove wall of the through groove, the mounting plate is fixedly connected to the outer top wall of the movable box, the mounting plate is located above the electrolyte impregnated cotton block, the automatic clamp and the rotating assembly are all arranged on the mounting plate, and the driving piece is arranged on the inner wall of the movable box.

Through adopting above-mentioned technical scheme, driving piece drive removes the case and removes, removes case, rotating assembly and automatic clamp and can follow ring track synchronous motion, realizes pulling the effect of guiding the foil. Moreover, the through groove can reduce the moving box from being separated from the ring track.

In a specific implementation manner, the driving piece comprises a driving motor, a driving gear and a supporting shaft, wherein the supporting shaft and the driving motor are fixedly connected to the inner wall of the movable box, the driving gear is rotatably connected to the supporting shaft, the driving motor is located at one side, deviating from the supporting shaft, of the driving gear, the motor shaft of the driving motor is fixedly connected with the driving gear, and the driving gear is meshed with the ring track.

Through adopting above-mentioned technical scheme, driving motor drives drive gear and rotates, and drive gear moves along the ring track promptly to realize the effect that the drive removes the case and remove. The support shaft is used for supporting the driving gear, and is beneficial to reducing shaking of the driving gear.

In a specific implementation manner, the rotating assembly comprises a rotating gear, a rotating motor, a rotating gear and a fixing frame, wherein the fixing frame and the rotating motor are fixedly connected to the moving seat, the rotating gear is rotationally connected to the fixing frame, the rotating gear is fixedly connected to a motor shaft of the rotating motor, the rotating gear is meshed with the rotating gear, and the automatic clamp is installed on the rotating gear.

Through adopting above-mentioned technical scheme, drive the motor drive and drive the rotation gear and rotate, drive the rotation gear and can drive the rotation gear rotation, automatic clamp and guide foil follow the synchronous rotation of rotation gear for the incision of guide foil opposite side can support to electrolyte flooding cotton piece on, and the mount is used for supporting the rotation gear, reduces and rotates the gear and rocks.

In a specific implementation manner, the automatic clamp comprises an automatic pushing piece, a spring and two clamping rods, the rotating gear comprises a gear body and a short shaft, the gear body is rotationally connected to the fixing frame, a jack is arranged on the gear body, two ends of the short shaft are fixedly connected to the hole wall of the jack, the two clamping rods are respectively arranged in the jack in a penetrating mode, the two clamping rods are respectively rotationally connected to the short shaft, the two clamping rods are mutually intersected, and the spring and the automatic pushing piece are respectively connected between the two clamping rods.

Through adopting above-mentioned technical scheme, the spring automatically pulls two clamp levers and rotates, and the one end that two clamp levers kept away from the spring is kept away from each other, is convenient for insert the guide foil between two clamp levers. The automatic pushing piece drives the two clamping rods to rotate, one ends of the two clamping rods, far away from the automatic pushing piece, are close to each other, and the two clamping rods can clamp the guide foil so as to facilitate pulling the guide foil to move.

In a specific embodiment, the automatic pushing member includes an elastic air bag connected between the two clamping bars, an air pump mounted on the movable seat, and an air pipe connected between the elastic air bag and the air pump.

Through adopting above-mentioned technical scheme, the air pump passes through the trachea to the gas transmission in the elastic air bag, and the elastic air bag inflation promotes two clamp levers and rotates for two clamp levers can press from both sides tight guide foil, and make the spring take place elastic deformation, when the air pump stops to aerifing in the elastic air bag, the gas in the elastic air bag passes through the trachea and discharges, and the spring automatically pulls two clamp levers and rotates, and loosens guide foil, consequently, through the cooperation of air pump, trachea, elastic air bag and spring, can realize pressing from both sides tight guide foil or loosen the effect of guide foil.

In a specific implementation manner, the annular rail comprises an annular rail body, supporting legs and a stop lever, wherein a plurality of the supporting legs are fixedly connected to the annular rail body, and two ends of the annular rail body are fixedly connected with at least one stop lever.

Through adopting above-mentioned technical scheme, the supporting leg is used for supporting the circular rail body, removes the seat and follows circular rail body circulation slip, can cyclic utilization, and the pin blocks the guide foil for the guide foil keeps stable at the removal in-process, reduces the guide foil and rocks at will.

In a second aspect, the application provides a process for forming an oxide film of an aluminum guide foil cutting edge, which adopts the following technical scheme:

an aluminum guide foil cut oxide film patch forming process comprises the following steps:

adding electrolyte into a formation tank of an aluminum guide foil cut oxide film patch forming system, immersing the electrolyte into an electrolyte-immersed cotton block, and applying an energized voltage of 6-35V to the electrolyte-immersed cotton block;

operating the automatic clamp to clamp the guide foil, wherein the notch at one side of the guide foil is abutted against the electrolyte impregnated cotton block, and the electrolyte supplements the notch at one side of the guide foil;

operating the movable seat to move along the ring track, sliding the guide foil along the electrolyte impregnated cotton block, and completing the repair of the notch on one side of the guide foil after the notch on one side of the guide foil slides on the electrolyte impregnated cotton block;

operating the rotating assembly to synchronously rotate the automatic clamp and the guide foil, enabling the notch on the other side of the guide foil to be abutted against the electrolyte impregnated cotton block on the other side of the ring track, and supplementing the notch on the other side of the guide foil by the electrolyte;

continuing to operate the moving seat to move, finishing the repair of the notch on the other side of the guide foil after the notch on the other side of the guide foil slides over the electrolyte-impregnated cotton block, and taking down the guide foil;

detecting the supplement forming condition of the guide foil, taking out the guide foil with qualified supplement forming, putting the guide foil with unqualified supplement forming into the guide foil to be supplement formed in the next batch, and performing supplement forming again.

By adopting the technical scheme, the 6-35V energized voltage is beneficial to the complementary formation, and the contact area of the guide foil and the electrolyte impregnated cotton block is small, so that the notches on two sides of the guide foil can be complementary, the consumption of the electrolyte can be reduced, and the purpose of saving the electrolyte is achieved.

In a specific embodiment, the electrolyte is a solution comprising at least one of citric acid or a citrate salt at a concentration of 0.1-10%.

By adopting the technical scheme, the electrolyte is adopted, and the complementary forming effect on the aluminum foil is better.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the application not only can complete the supplement formation of the notch of the guide foil, but also can reduce the consumption of electrolyte, thereby being beneficial to saving the electrolyte;

2. the application can realize the effect of clamping or loosening the guide foil through the matching of the air pump, the air pipe, the elastic air bag and the spring;

3. the movable seat provided by the application can circularly slide along the annular rail body, can be circularly used, and the stop lever is beneficial to reducing random shaking of the guide foil.

Drawings

Fig. 1 is a schematic diagram of a system for repairing an oxide film on a notch of an aluminum guide foil in an embodiment of the application.

Fig. 2 is an enlarged view at a in fig. 1.

Fig. 3 is an enlarged view at B in fig. 1.

Fig. 4 is an enlarged view at C in fig. 1.

Fig. 5 is a schematic view of a structure of a movable base and a rotating assembly according to an embodiment of the present application.

Fig. 6 is a cross-sectional view of a mobile station in an embodiment of the application.

Fig. 7 is a schematic view of an exploded view of a rotating assembly in accordance with an embodiment of the present application.

Reference numerals illustrate:

1. a circular orbit; 11. a ring rail body; 111. a straight rail; 112. an arc rail; 12. support legs; 13. a stop lever; 131. bending a rod; 132. a vertical rod; 2. forming a groove; 21. impregnating cotton blocks with electrolyte; 22. a tank body; 23. a push plate; 24. a cylinder; 25. a connecting rod; 3. a movable seat; 31. a moving case; 311. a through groove; 32. a mounting plate; 33. a driving member; 331. a driving motor; 332. a drive gear; 333. a support shaft; 4. automatic clamping; 41. an automatic pushing member; 411. an elastic air bag; 412. an air pump; 413. an air pipe; 42. a spring; 43. a clamping rod; 5. a rotating assembly; 51. rotating the gear; 511. a gear body; 5111. a jack; 5112. a shaft hole; 512. a short shaft; 52. a drive motor; 53. a drive gear; 54. a fixing frame; 541. a right angle lever; 542. and a fixed shaft.

Detailed Description

The application is described in further detail below with reference to fig. 1-7.

In the description of the present application, it should be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings are merely for convenience in describing the present application and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application.

The embodiment of the application discloses an aluminum guide foil cutting oxide film repair forming system.

Referring to fig. 1 and 2, the aluminum guide foil cut oxide film patch forming system includes a ring rail 1, a formation groove 2, a movable base 3, an automatic clamp 4, and a rotating assembly 5. At least two formation grooves 2 are arranged, all formation grooves 2 encircle the circumference of the circular track 1, two formation grooves 2 are arranged in the embodiment, and electrolyte impregnated cotton blocks 21 are arranged in the formation grooves 2. The movable seats 3 are provided with a plurality of movable seats 3, all the movable seats 3 are connected to the ring track 1 in a sliding mode, and the rotary assembly 5 and the automatic clamp 4 are arranged on the movable seats 3.

Electrolyte is injected into the formation tank 2, and the electrolyte is 0.1-10% of solution containing at least one of citric acid or citrate, and the electrolyte in this example is aqueous solution of citric acid with a temperature of 70 ℃, a concentration of 10% and a pH value of 6.0. The electrolyte is immersed in the electrolyte-impregnated cotton block 21, and an energizing voltage of 6 to 35V is applied to the electrolyte-impregnated cotton block 21, and in this embodiment, an energizing voltage of 13V is applied to the electrolyte-impregnated cotton block 21. Then, the guide foil is clamped on the automatic clamp 4, the notch of the guide foil is abutted on the electrolyte impregnated cotton block 21, the movable seat 3 is operated to move along the ring track 1, the guide foil moves synchronously along the movable seat 3, when the notch on one side of the guide foil completes the supplement formation, the automatic clamp 4 is driven to rotate by the operation rotating assembly 5, the notch on the other side of the guide foil is abutted on the electrolyte impregnated cotton block 21, and after the notches on both sides of the guide foil complete the supplement formation, the guide foil is taken down to carry out the supplement formation on the next guide foil.

Referring to fig. 1, the endless track 1 includes an endless track body 11, support legs 12 and a bar 13, the endless track body 11 includes two straight tracks 111 and an arc track 112, the two straight tracks 111 are parallel to each other, the arc track 112 is located at both ends of the straight track 111, and the arc track 112 is integrally connected with an end of the straight track 111. The support legs 12 are provided in plurality, and the support legs 12 are welded below the straight rail 111. The stop lever 13 comprises a bending rod 131 and a vertical rod 132, the bending rod 131 is an L-shaped rod, one end of the bending rod 131 is welded below the arc rail 112, the other end of the bending rod 131 extends to one side of the arc rail 112, which is away from the straight rail 111, and the vertical rod 132 is welded on the bending rod 131.

Referring to fig. 3, the formation tank 2 includes a tank body 22, a push plate 23, a cylinder 24, and a connecting rod 25, the tank body 22 being placed outside the straight rail 111, and the length direction of the tank body 22 being the same as the length direction of the straight rail 111. The cylinder 24 is riveted to the end wall of the tank body 22, and the cylinder 24 is disposed in the vertical direction. The connecting rod 25 is L-shaped, and the one end of connecting rod 25 is riveted at the flexible end of cylinder 24, and the other end of connecting rod 25 is riveted on push pedal 23, and push pedal 23 is located cell body 22, and electrolyte flooding cotton piece 21 bonds on the upper surface of push pedal 23.

The cylinder 24 is extended, the pushing plate 23 pushes the electrolyte impregnated cotton block 21 to move upwards, and when the electrolyte impregnated cotton block 21 is abutted against the notch of the guide foil, the notch of the guide foil is complemented. The cylinder 24 is shortened, and the electrolyte impregnated cotton block 21 moves downward, and the electrolyte is immersed in the electrolyte impregnated cotton block 21.

Referring to fig. 4 and 5, the movable base 3 includes a movable case 31, a mounting plate 32, and a driving member 33, a through groove 311 is provided in an end wall of the movable case 31, the through groove 311 penetrates a bottom wall and two opposite end walls of the movable case 31, a straight rail 111 is inserted into the through groove 311, and the straight rail 111 abuts against a groove wall of the through groove 311. A mounting plate 32 is welded to the top wall of the mobile box 31, the mounting plate 32 extending above the channel 22.

Referring to fig. 5 and 6, the driving part 33 is located in the moving case 31, the driving part 33 includes a driving motor 331, a driving gear 332 and a supporting shaft 333, the driving motor 331 is riveted on an inner wall of the moving case 31, the supporting shaft 333 is welded on an inner wall of the moving case 31 opposite to the driving motor 331, and axial directions of the driving motor 331 and the supporting shaft 333 are perpendicular to a length direction of the straight rail 111. The driving gear 332 is welded on the motor shaft of the driving motor 331, a rotating hole is formed in the side wall, deviating from the driving motor 331, of the driving gear 332, and the supporting shaft 333 is inserted into the rotating hole and is abutted to the hole wall.

Referring to fig. 5 and 7, the rotation assembly 5 includes a rotation gear 51, a rotation motor 52, a rotation gear 53, and a fixing frame 54, the fixing frame 54 includes a right angle lever 541 and a fixing shaft 542, the right angle lever 541 is an L-shaped lever, one end of the right angle lever 541 is welded to a lower surface of the mounting plate 32, and the fixing shaft 542 is welded to the other end of the right angle lever 541. The rotary gear 51 is provided with a shaft hole 5112, and the fixed shaft 542 is inserted into the shaft hole 5112 and abuts against the hole wall.

The rotary gear 51 comprises a gear body 511 and a short shaft 512, the shaft hole 5112 is arranged on the gear body 511, the rotary gear 51 is provided with an inserting hole 5111, the short shaft 512 is positioned in the inserting hole 5111, and two ends of the short shaft 512 are welded on the wall of the inserting hole 5111. The driving motor 52 is riveted on the lower surface of the mounting plate 32, the driving gear 332 is welded on the motor shaft of the driving motor 331, and the driving gear 332 is engaged with the gear body 511.

Referring to fig. 7, the automatic clamp 4 includes an automatic pusher 41, a spring 42, and two clamp bars 43, both of which 43 are inserted into the insertion hole 5111, and both of which 43 cross each other. Vertical holes are formed in the two clamping rods 43, and the short shafts 512 penetrate through the vertical holes and are abutted against the hole walls. The automatic pushing member 41 and the spring 42 are located at the same end of the clamp bars 43, the automatic pushing member 41 and the spring 42 are connected between the two clamp bars 43, and the spring 42 applies a pulling force to the two clamp bars 43.

The automatic pushing member 41 comprises an elastic air bag 411, an air pump 412 and an air pipe 413, wherein the elastic air bag 411 is connected between the two clamping rods 43, the air pump 412 is riveted on the lower surface of the mounting plate 32, one end of the air pipe 413 is integrally connected with the elastic air bag 411, the other end of the air pipe 413 is fixedly connected with the air pump 412, and the air pump 412 and the elastic air bag 411 are both communicated with the air pipe 413.

The embodiment of the application also discloses a process for repairing and forming the aluminum guide foil cut oxide film.

The aluminum guide foil cut oxide film repair forming process comprises the following steps:

electrolyte is added into the tank body 22, the electrolyte impregnated cotton block 21 is impregnated into the electrolyte, and after the electrolyte is impregnated into the electrolyte impregnated cotton block 21, the electrolyte impregnated cotton block 21 is electrified, and the voltage is 13V;

one end of the guide foil is inserted between the two clamping bars 43, the air pump 412 is started to inflate the elastic air bag 411, the elastic air bag 411 automatically expands, and the elastic air bag 411 pushes the two clamping bars 43 to rotate and clamp the guide foil.

The driving motor 331 is started, the driving gear 332 is rotated, the moving case 31 is slid along the straight rail 111, and the automatic clamp 4 is operated to clamp the guide foil when the other end of the guide foil is moved to the other moving case 31 side. Then the cylinder 24 is started to extend, the push plate 23 pushes the electrolyte-impregnated cotton block 21 to move upwards, and when the electrolyte-impregnated cotton block 21 is abutted against the notch of the guide foil, the cylinder 24 is closed, and the electrolyte supplements the notch of the guide foil.

The moving box 31 pulls the guide foil to move, the guide foil slides on the surface of the electrolyte-impregnated cotton block 21, and after all the cuts on one side of the guide foil slide on the surface of the electrolyte-impregnated cotton block 21, the supplement of the cuts on one side of the guide foil is completed.

Then, the starting cylinder 24 is shortened, the electrolyte impregnated cotton block 21 is lowered, the moving box 31 continues to move, and enters the other straight rail 111 after passing through the arc rail 112, and the foil is guided to slide along the surface of the vertical rod 132 to above the electrolyte impregnated cotton block 21 on the other side of the straight rail 111.

When the driving motor 52 is started and the driving gear 53 drives the rotating gear 51 to rotate, and when the notch on the other side of the guide foil faces the electrolyte impregnated cotton block 21, the starting cylinder 24 stretches, the electrolyte impregnated cotton block 21 is abutted against the notch to be formed on the other side of the guide foil, and the electrolyte supplements the notch to be formed on the other side of the guide foil.

The cut to be repaired on the other side of the guide foil is completed after all the cuts on the electrolyte impregnated cotton block 21 are scratched.

Then, the actuating cylinder 24 is shortened, the electrolyte impregnated cotton block 21 is lowered, the air pump 412 is turned off, the spring 42 automatically pulls the clamp lever 43 to rotate, and the guide foil is removed.

Checking the supplement forming condition of the cuts at the two sides of the guide foil, taking away the guide foil with qualified detection result, putting the guide foil with unqualified detection result into the guide foil to be supplement formed in the next batch, continuing the steps, and performing supplement forming again.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (6)

1. An aluminum guide foil cut oxide film repair forming system is characterized in that: the automatic foil clamping device comprises a ring track (1), a formation groove (2) and a movable seat (3), wherein a plurality of formation grooves (2) are formed in the periphery of the ring track (1), the movable seats (3) are slidably connected to the ring track (1), automatic clamps (4) for clamping a guide foil are arranged on the movable seat (3), a rotating assembly (5) for driving the automatic clamps (4) to rotate is arranged on the movable seat (3), electrolyte impregnated cotton blocks (21) are arranged in the formation groove (2), and the electrolyte impregnated cotton blocks (21) are arranged below the automatic clamps (4); the chemical forming groove (2) comprises a groove body (22), a push plate (23), an air cylinder (24) and a connecting rod (25), wherein the push plate (23) is arranged in the groove body (22), the air cylinder (24) is fixedly connected to the outer wall of the groove body (22), the connecting rod (25) is fixedly connected to the telescopic end of the air cylinder (24), the connecting rod (25) is fixedly connected with the push plate (23), and the electrolyte impregnated cotton block (21) is fixed on the push plate (23); the movable seat (3) comprises a movable box (31), a mounting plate (32) and a driving piece (33) for driving the movable box (31) to move, a through groove (311) is formed in the movable box (31), the ring rail (1) is arranged in the through groove (311) in a penetrating mode, the ring rail (1) is in butt joint with the groove wall of the through groove (311), the mounting plate (32) is fixedly connected to the outer top wall of the movable box (31), the mounting plate (32) is located above the electrolyte impregnated cotton block (21), the automatic clamp (4) and the rotating assembly (5) are both arranged on the mounting plate (32), and the driving piece (33) is arranged on the inner wall of the movable box (31); the driving piece (33) comprises a driving motor (331), a driving gear (332) and a supporting shaft (333), the supporting shaft (333) and the driving motor (331) are fixedly connected to the inner wall of the moving box (31), the driving gear (332) is rotatably connected to the supporting shaft (333), the driving motor (331) is positioned at one side, deviating from the supporting shaft (333), of the driving gear (332), of the driving motor (331), a motor shaft of the driving motor (331) is fixedly connected with the driving gear (332), and the driving gear (332) is meshed with the circular track (1); the rotating assembly (5) comprises a rotating gear (51), a rotating motor (52), a rotating gear (53) and a fixing frame (54), wherein the fixing frame (54) and the rotating motor (52) are fixedly connected to the movable seat (3), the rotating gear (51) is rotationally connected to the fixing frame (54), the rotating gear (53) is fixedly connected to a motor shaft of the rotating motor (52), the rotating gear (53) is meshed with the rotating gear (51), and the automatic clamp (4) is installed on the rotating gear (51).

2. The aluminum guide foil cutoff oxide film patch forming system according to claim 1, wherein: automatic press from both sides (4) including automatic impeller (41), spring (42) and two clamp levers (43), rotation gear (51) are including gear body (511) and minor axis (512), gear body (511) rotate and are connected on mount (54), be equipped with jack (5111) on gear body (511), the both ends of minor axis (512) are all fixed connection on the pore wall of jack (5111), two clamp levers (43) are all worn to locate in jack (5111), two clamp levers (43) are all rotated and are connected on minor axis (512), two clamp levers (43) are crisscrossed each other, spring (42) with automatic impeller (41) are all connected between two clamp levers (43).

3. The aluminum guide foil cutoff oxide film patch forming system according to claim 2, wherein: the automatic pushing piece (41) comprises an elastic air bag (411), an air pump (412) and an air pipe (413), wherein the elastic air bag (411) is connected between the two clamping rods (43), the air pump (412) is installed on the movable seat (3), and the air pipe (413) is connected between the elastic air bag (411) and the air pump (412).

4. The aluminum guide foil cutoff oxide film patch forming system according to claim 1, wherein: the annular track (1) comprises an annular track body (11), supporting legs (12) and a stop lever (13), wherein a plurality of the supporting legs (12) are fixedly connected to the annular track body (11), and two ends of the annular track body (11) are fixedly connected with at least one stop lever (13).

5. A patch forming process using the aluminum guide foil cut oxide film patch forming system according to any one of claims 1 to 4, characterized by comprising the steps of:

adding electrolyte into a formation tank (2) of an aluminum guide foil cut oxide film repair forming system, immersing the electrolyte into an electrolyte-immersed cotton block (21), and applying an energized voltage of 6-35V to the electrolyte-immersed cotton block (21);

the automatic clamp (4) is operated to clamp the guide foil, the notch at one side of the guide foil is abutted against the electrolyte impregnated cotton block (21), and the electrolyte supplements the notch at one side of the guide foil;

the movable seat (3) is operated to move along the annular track (1), the guide foil slides along the electrolyte impregnated cotton block (21), and after all the cuts on one side of the guide foil slide on the electrolyte impregnated cotton block (21), the supplement formation of the cuts on one side of the guide foil is completed;

operating the rotating assembly (5) to synchronously rotate the automatic clamp (4) and the guide foil, enabling the notch on the other side of the guide foil to be abutted against the electrolyte impregnated cotton block (21) on the other side of the ring track (1), and supplementing the notch on the other side of the guide foil by the electrolyte;

continuing to operate the moving seat (3) to move, and after all the incisions on the other side of the guide foil slide on the electrolyte impregnated cotton block (21), completing the repair of the incisions on the other side of the guide foil, and taking down the guide foil;

detecting the supplement forming condition of the guide foil, taking out the guide foil with qualified supplement forming, putting the guide foil with unqualified supplement forming into the guide foil to be supplement formed in the next batch, and performing supplement forming again.

6. The patch-forming process of claim 5, wherein the electrolyte is a solution comprising at least one of citric acid or a salt of citric acid at a concentration of 0.1-10%.