CN114694982B

CN114694982B - Aluminum guide foil production system with all-around oxide film coverage

Info

Publication number: CN114694982B
Application number: CN202210536690.7A
Authority: CN
Inventors: 陈德庆; 濮利建; 濮丹飞
Original assignee: Tengxian Feile Electronic Technology Co ltd
Current assignee: Tengxian Feile Electronic Technology Co ltd
Priority date: 2022-05-17
Filing date: 2022-05-17
Publication date: 2023-06-06
Anticipated expiration: 2042-05-17
Also published as: CN114694982A

Abstract

The application relates to an aluminum guide foil production system with all-around oxide films, and relates to the technical field of aluminum guide foil formation, comprising an unreeling mechanism, a slitting mechanism, a formation mechanism, a cleaning mechanism, a surface treatment mechanism, a drying mechanism and a reeling mechanism; the formation mechanism comprises a formation groove, a plurality of groups of driving rollers are arranged on the formation groove, each group of driving rollers comprises two driving rollers, the two driving rollers are arranged in a staggered manner, a plurality of separation grooves are formed in the two driving rollers in a staggered manner, a plurality of groups of bottom rollers are arranged in the formation groove, each group of bottom rollers comprises two driving rollers, and separation grooves are formed in each bottom roller in a staggered manner; after the aluminum foil is cut by the cutting mechanism, the odd aluminum foil strips respectively pass through the separation groove on one driving roller in the group of driving rollers and the separation groove on one bottom roller in the group of bottom rollers, and the even aluminum foil strips respectively pass through the separation groove on the other driving roller and the separation groove on the other bottom roller. The application has the effect of forming a plurality of aluminum foil strips at one time, and is simple and convenient to operate.

Description

Aluminum guide foil production system with all-around oxide film coverage

Technical Field

The application relates to the field of aluminum guide foil formation, in particular to an aluminum guide foil production system with all-around oxide film coverage.

Background

The aluminum foil can be formed into a layer of oxide film on all surfaces by a formation technology, and the existing enterprises generally need more equipment in the production line through the steps of unreeling, formation, cleaning, surface treatment, cleaning, drying, rolling and the like when producing the aluminum foil.

In actual production, manufacturing enterprises can produce aluminum foils with wider widths, such as aluminum foils with the widths of 500mm and more, after the production is completed, actual users can cut the aluminum foils into specific widths according to actual requirements, and once the aluminum foils are cut, the cutting openings of the aluminum foils are free of oxide films, so that the subsequent normal use is worried. Therefore, how to efficiently manufacture aluminum guide foils with various widths and full coverage of four-sided oxide films at high level is a product upgrade level problem that is urgently needed to be solved at present.

Disclosure of Invention

In order to enable enterprises to manufacture high-quality guide aluminum foils with various widths at high level and high efficiency, the application provides an aluminum guide foil production system with full coverage of four-side oxide films.

The aluminum guide foil production system with all-covered four-side oxide films adopts the following technical scheme:

the aluminum guide foil production system with the full coverage of the four-side oxide film comprises an unreeling mechanism, a slitting mechanism, a formation mechanism, a cleaning mechanism, a surface treatment mechanism, a cleaning mechanism, a drying mechanism and a reeling mechanism which are sequentially arranged;

the formation mechanism comprises formation grooves, wherein a plurality of groups of driving rollers are arranged on the formation grooves, each group of driving rollers comprises two driving rollers, the two driving rollers are arranged in an up-down staggered mode, a plurality of separation grooves are formed in the two driving rollers in a staggered mode, a plurality of groups of bottom rollers are arranged in the formation grooves, each group of bottom rollers comprises two rollers which are arranged in an up-down staggered mode, separation grooves are formed in each bottom roller, and the separation grooves in the two bottom rollers are arranged in a staggered mode;

after the aluminum foil is cut by the slitting mechanism, the formed aluminum foil strips are ordered in the width direction of the aluminum foil, odd aluminum foil strips respectively pass through the separation groove on one driving roller in a group of driving rollers and the separation groove on one bottom roller in a group of bottom rollers, and even aluminum foil strips respectively pass through the separation groove on the other driving roller and the separation groove on the other bottom roller.

Through adopting above-mentioned technical scheme, the aluminium foil is cut into a plurality of aluminium foil strips after cutting the mechanism, utilize driving roller and bottom roll to separate odd aluminium foil strip and even aluminium foil strip, make a plurality of aluminium foil strips be divided into two sets of, two sets of aluminium foil strips all get into formation groove and become and be difficult to take place skew, overlap, friction each other, thereby the formation of a plurality of aluminium foil strips of various width in electrolyte can be accomplished once only, all generate the oxide film on four faces of aluminium foil strip, easy operation is convenient, need not to use many production lines can accomplish the formation of a plurality of various width aluminium foil strips.

In a specific embodiment, the width of the separator groove is equal to the width of the aluminum foil strip, and the width of the separator groove is equal to the width of the aluminum foil strip.

Through adopting above-mentioned technical scheme for a plurality of aluminium foil strips can be synchronous along the direction of rolling through formation groove, the removal direction of having overcome aluminium foil strips takes place skew, overlap, frictioned defect.

In a specific implementation manner, a negative plate is arranged between two adjacent groups of driving rollers in the formation groove, the negative plate is connected with a negative electrode of a direct current power supply, and an aluminum foil which is not cut in the unreeling mechanism is connected with a positive electrode of the direct current power supply.

Through adopting above-mentioned technical scheme, if directly put through the power positive with the backing roll in the formation groove, because interval is less between the spread groove on the backing roll, behind the switch-on positive, the voltage that the spread groove produced is too big, makes the mutual interference easily produce between the aluminium foil strip to influence formation effect, and directly put through the power positive with the aluminium foil that does not cut in cutting mechanism, then can effectively reduce the possibility of producing mutual interference between the aluminium foil strip after the cutting, effectively ensured formation effect.

In a specific embodiment, the formation mechanism is provided with a plurality of formation grooves in sequence, and the voltages in the plurality of formation grooves are increased in sequence.

By adopting the technical scheme, if only one formation groove is used, the formation can be completed by using larger voltage, the mutual interference between the aluminum foil strips is easy to generate due to the larger voltage, and the formation grooves are arranged, so that the voltage is increased in a grading manner, and the possibility of the mutual interference between the aluminum foil strips can be reduced when the formation is completed.

In a specific embodiment, the aluminum foil which is not cut in the unreeling mechanism is aluminum foil after formation or aluminum foil which is not formed.

By adopting the technical scheme, the aluminum foil which is formed or is not formed can be cut, and then the aluminum foil strip is correspondingly formed.

In a specific implementation manner, the cleaning mechanism comprises a cleaning tank, a plurality of groups of driving rollers are also arranged on the cleaning tank, a group of bottom rollers are also arranged in the cleaning tank, two groups of cleaning plates are arranged in the cleaning tank, each group comprises two cleaning plates, a plurality of spray heads are arranged on opposite sides of the two cleaning plates, an odd aluminum foil passes through between the two cleaning plates in one group, and an even aluminum foil passes through between the two cleaning plates in the other group.

By adopting the technical scheme, the odd aluminum foil and the even aluminum foil can pass through the cleaning tank at the same time, and interference can not be generated between the odd aluminum foil and the even aluminum foil, so that the cleaning effect can be effectively ensured.

In a specific implementation manner, two groups of water scraping rods are arranged in the cleaning tank, each group of water scraping rods comprises two aluminum foil sheets, an odd aluminum foil sheet passes through the space between the two water scraping rods in one group, an even aluminum foil sheet passes through the space between the two water scraping rods in the other group, and the water scraping rods are attached to the aluminum foil sheets.

By adopting the technical scheme, the water on the aluminum foil is scraped by the water scraping rod, the possibility that the surface treatment effect is affected due to the fact that the aluminum foil brings the water into the surface treatment mechanism is reduced, meanwhile, water can be recovered, and the waste of water resources is reduced.

In a specific implementation manner, the drying mechanism comprises a drying box, an inlet and an outlet are formed in the drying box, two conveying rollers are arranged at the inlet and the outlet of the drying box, a plurality of isolation grooves are formed in the two conveying rollers in a staggered mode, and odd aluminum foils and odd foils respectively pass through the isolation grooves in one conveying roller.

By adopting the technical scheme, the odd aluminum foil and the odd aluminum foil can pass through the drying box without interference.

In a specific embodiment, the widths of the aluminum foil strips formed after the aluminum foil is cut by the cutting mechanism are equal or different.

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

1. according to the aluminum foil forming machine, the aluminum foil is cut into a plurality of strips by the cutting mechanism, and the odd aluminum foil filtering sheets and the even aluminum foil filtering sheets are separated by the driving roller and the bottom roller, so that the odd aluminum foil filtering sheets and the even aluminum foil filtering sheets can pass through the forming grooves and are not easy to deviate, overlap and rub, the forming quality can be effectively ensured, and meanwhile, the forming of a plurality of aluminum foil strips can be completed without a plurality of production lines, so that the operation is simple and convenient;

2. according to the aluminum foil forming device, the negative electrode plate is connected with the negative electrode of the power supply in the forming groove, and the aluminum foil is connected with the positive electrode of the power supply in the cutting mechanism, so that the possibility of mutual interference between aluminum foil sheets is reduced, and the forming quality is effectively ensured;

3. the aluminum foil is washed by the spray head, so that impurities or formation liquid on the surface of the aluminum foil is removed, water is recycled into the washing tank by the water scraping rod, water resources are saved, and the possibility that water enters the surface treatment mechanism to influence the surface treatment effect is reduced.

Drawings

FIG. 1 is a schematic diagram of the overall structure of an aluminum guide foil production system with full coverage of four-sided oxide films according to an embodiment of the present application;

FIG. 2 is a schematic diagram of the overall structure of the aluminum guide foil production system with full coverage of four-sided oxide films according to the embodiment of the present application;

FIG. 3 is a schematic diagram of the structure of the unwind, slit and transport mechanisms of the embodiments of the present application;

FIG. 4 is a cross-sectional view of an embodiment of the present application formed into a trough;

FIG. 5 is a cross-sectional view of a cleaning tank according to an embodiment of the present application;

FIG. 6 is a cross-sectional view of a surface treatment tank according to an embodiment of the present application;

FIG. 7 is a schematic view of the structure of a drying box and a winding mechanism according to an embodiment of the present application;

in the figure, 1, an unreeling mechanism; 11. unreeling rack; 12. an unreeling roller; 13. a motor; 2. a slitting mechanism; 21. cutting the frame; 22. a slitting roller; 23. a dividing knife; 24. a guide roller; 3. a conveying mechanism; 31. a conveying frame; 32. a conveying roller; 321. a transfer tank; 4. a formation mechanism; 41. forming a groove; 410. a mounting frame; 42. a driving roller; 43. a bottom roller; 431. a separation tank; 44. a hanging bracket; 441. a negative plate; 5. a cleaning mechanism; 51. a cleaning tank; 52. cleaning the plate; 521. a spray head; 53. a wiper lever; 6. a surface treatment mechanism; 61. a surface treatment tank; 7. a drying mechanism; 71. a drying box; 72. a conveying roller; 8. a winding mechanism; 81. a winding frame; 82. and (5) a wind-up roller.

Detailed Description

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

The embodiment of the application discloses an aluminum guide foil production system with all-covered four-sided oxide films. Referring to fig. 1 and 2, the aluminum guide foil production system with full coverage of four-side oxide films comprises an unreeling mechanism 1, a slitting mechanism 2, a conveying mechanism 3, a formation mechanism 4, a cleaning mechanism 5, a surface treatment mechanism 6, a cleaning mechanism 5, a drying mechanism 7 and a reeling mechanism 8 which are sequentially arranged, wherein after the formed or non-formed wider aluminum foil is unreeled by the unreeled mechanism 1, the aluminum foil is sequentially slit by the slitting mechanism 2, the conveying mechanism 3 conveys, the formation of the formation mechanism 4, the cleaning of the cleaning mechanism 5, the treatment of the surface treatment mechanism 6 and the drying of the drying mechanism 7, and finally the aluminum foil is reeled into a plurality of aluminum foil rolls with narrower widths.

Referring to fig. 3, the unreeling mechanism 1 includes an unreeling frame 11, an unreeling roller 12 and a motor 13 connected to the unreeling roller 12 are arranged on the unreeling frame 11, and the unreeling roller 12 is driven to rotate by the motor 13, so that unreeling of aluminum foil is achieved. The slitting mechanism 2 comprises a slitting frame 21, two slitting rollers 22 which are distributed up and down and a motor 13 which is connected with the slitting rollers 22 are arranged on the slitting frame 21, a plurality of slitting knives 23 are arranged on the slitting rollers 22, a guide roller 24 is arranged on one side, close to the unreeling frame 11, of the slitting frame 21, an aluminum foil sheet can accurately enter between the two slitting rollers 22 by the aid of the guide roller 24, the aluminum foil sheet is cut into a plurality of aluminum foil strips with equal widths by the aid of the slitting knives 23, and in other embodiments, the aluminum foil sheet can be cut into a plurality of aluminum foil strips with unequal widths according to actual requirements.

Referring to fig. 3, the transfer mechanism 3 includes a transfer frame 31 and two transfer rollers 32 provided on the transfer frame 31, and a motor 13 connected to the transfer rollers 32 is provided on the transfer frame 31 to drive the transfer rollers 32 to rotate. The two conveying rollers 32 are distributed up and down and are arranged in a staggered mode, a plurality of conveying grooves 321 are formed in the two conveying rollers 32, the conveying grooves 321 in the two conveying rollers 32 are distributed in a staggered mode, and the width of the conveying grooves 321 is equal to that of the aluminum foil strips. The aluminum foil strips formed by cutting are divided into odd aluminum foil strips and even aluminum foil strips in the width direction of the aluminum foil, a plurality of odd aluminum foil strips respectively pass through the conveying grooves 321 on the conveying roller 32 below, and a plurality of even aluminum foil strips respectively pass through the conveying grooves 321 on the conveying roller 32 above, so that a plurality of aluminum foil strips are divided into two groups of odd aluminum foil strips and even aluminum foil strips, and the moving routes of the odd aluminum foil strips and the even aluminum foil strips are mutually separated.

Referring to fig. 4, the formation mechanism 4 includes a formation groove 41, three groups of driving rollers 42 are disposed at an opening at the top of the formation groove 41 through a mounting plate, each group of driving rollers 42 includes two driving rollers 42 and the two driving rollers 42 are distributed in a vertically staggered manner, separation grooves are formed in the two driving rollers 42, the separation grooves in the two driving rollers 42 are distributed in a staggered manner, and the driving rollers 42 are driven by a motor 13 disposed on the mounting plate. Two groups of bottom rollers 43 close to the bottom of the formation groove 41 are arranged in the formation groove 41 through a mounting frame 410, the bottom rollers 43 are connected with the mounting frame 410 through bearings, the two groups of bottom rollers 43 are respectively positioned between two adjacent groups of driving rollers 42, each group of bottom rollers 43 comprises two bottom rollers 43, separation grooves 431 are formed in the two bottom rollers 43, and the separation grooves 431 in the two bottom rollers 43 are distributed in a staggered mode. A plurality of odd aluminum foil strips respectively pass through the separation groove on the lower driving roller 42 and the separation groove 431 on the lower bottom roller 43, and a plurality of even aluminum foil strips respectively pass through the separation groove on the upper driving roller 42 and the separation groove 431 on the upper bottom roller 43, so that the odd aluminum foil strips and the even aluminum foil strips can pass through the formation groove 41 and complete the formation process under the condition of no mutual interference, the possibility of offset, mutual overlapping and friction of the aluminum foil strips in the formation process is reduced, and the formation quality is effectively ensured. In the present embodiment, the driving roller 42 and the bottom roller 43 are both made of an insulating material.

Referring to fig. 4, two hangers 44 are provided at the opening of the top of the formation groove 41, one negative plate 441 is provided on each hanger 44, and the two negative plates 441 are respectively located between two adjacent sets of driving rollers 42. In the formation, the negative electrode plate 441 is lower than the liquid surface of the formation liquid in the formation tank 41, the negative electrode plate 441 is connected with the power negative electrode, and the aluminum foil sheet which is not cut in the unreeling mechanism 1 is connected with the power positive electrode, so that the formation operation can be performed, and the possibility of mutual interference between the aluminum foil strips when the power positive electrode is directly connected with the bottom roller 43 can be reduced. In this embodiment, four formation grooves 41 are sequentially arranged, and the voltages in the formation grooves 41 are sequentially increased, so that the possibility of mutual interference or even damage of the aluminum foil strips due to overlarge voltages is reduced.

Referring to fig. 5, the cleaning mechanism 5 includes a cleaning tank 51, such as an assimilation tank 41, two sets of identical driving rollers 42 are also disposed at the opening at the top of the cleaning tank 51, a set of identical bottom rollers 43 near the bottom of the cleaning tank 51 are disposed in the cleaning tank 51 through a mounting frame 410, a plurality of odd aluminum foil strips respectively pass through a separating tank on the lower driving roller 42 and a separating tank 431 on the lower bottom roller 43, and a plurality of even aluminum foil strips respectively pass through a separating tank on the upper driving roller 42 and a separating tank 431 on the upper bottom roller 43.

Referring to fig. 5, two sets of cleaning plates 52 and two sets of wiper rods 53 are disposed in the cleaning tank 51, the two sets of cleaning plates 52 and the two sets of wiper rods 53 are respectively matched with one bottom roller 43, each set of cleaning plates 52 includes two cleaning plates 52, opposite sides of the two cleaning plates 52 are provided with a plurality of spray heads 521, and each set of wiper rods 53 includes two wiper rods 53. The odd aluminum foil strips correspondingly pass through the group of cleaning plates 52 and the group of water scraping rods 53, the even aluminum foil strips correspondingly pass through the group of cleaning plates 52 and the group of water scraping rods 53, the spray head 521 is used for washing the aluminum foil strips, and the water scraping rods 53 are used for scraping the water on the aluminum foil strips, so that the possibility that the aluminum foil strips bring the water into the surface treatment mechanism 6 is reduced.

Referring to fig. 6, the surface treatment mechanism 6 includes a surface treatment tank 61, like the formation tank 41, two identical driving rolls 42 are also provided at the opening of the top of the surface treatment tank 61, a set of identical bottom rolls 43 near the bottom of the surface treatment tank 61 are provided in the surface treatment tank 61 through a mounting frame 410, a plurality of odd aluminum foil strips respectively pass through the separation grooves on the driving rolls 42 below and the separation grooves 431 on the bottom rolls 43 below, and a plurality of even aluminum foil strips respectively pass through the separation grooves on the driving rolls 42 above and the separation grooves 431 on the bottom rolls 43 above. After the aluminum foil strip passes through the surface treatment tank 61, a passivation film may be formed on the oxide film on the surface thereof to protect the oxide film.

Referring to fig. 7, the drying mechanism 7 includes a drying box 71, the drying box 71 is provided with an inlet and an outlet, the drying box 71 is provided with two conveying rollers 72 which are distributed in an up-down staggered manner at the inlet and the outlet, a plurality of isolation grooves are formed in the two conveying rollers 72 in a staggered manner, a plurality of odd aluminum foil strips respectively pass through the isolation grooves on the conveying rollers 72 positioned below, and a plurality of even aluminum foil strips respectively pass through the isolation grooves on the conveying rollers 72 positioned above, so that the odd aluminum foil strips and the even aluminum foil strips can pass through the drying box 71 without mutual interference and are dried. The winding mechanism 8 comprises a winding frame 81, two winding rollers are distributed on the winding frame 81 up and down, the winding rollers are driven by a motor 13, and odd aluminum foil strips and even aluminum foil strips are wound by the two winding rollers respectively, so that the aluminum foil rolls are convenient for workers to collect.

The implementation principle of the embodiment of the application is as follows: after being cut into a plurality of aluminum foil strips by the slitting mechanism 2, the aluminum foil can be divided into an odd aluminum foil strip and an even aluminum foil strip under the action of the conveying roller 32, and the odd aluminum foil strip and the even aluminum foil strip can pass through the formation groove 41, the cleaning groove 51, the surface treatment groove 61 and the cleaning groove 51 in sequence without mutual interference under the action of the driving roller 42 and the bottom roller 43, pass through the drying box 71 under the action of the conveying roller 72, and finally are wound by the winding roller, so that the integral formation operation is completed. In the integral formation operation, the formation of a plurality of aluminum foil strips can be completed without using a plurality of production lines, and the operation is simple and convenient.

The embodiments of this embodiment are all preferred embodiments of the present application, and are not intended to limit the scope of the present application, in which like parts are denoted by like reference numerals. Therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims

1. Four sides oxide film all-covered aluminium guide foil production system, its characterized in that: the device comprises an unreeling mechanism (1), a slitting mechanism (2), a formation mechanism (4), a cleaning mechanism (5), a surface treatment mechanism (6), a cleaning mechanism (5), a drying mechanism (7) and a reeling mechanism (8) which are sequentially arranged;

the formation mechanism (4) comprises formation grooves (41), a plurality of groups of driving rollers (42) are arranged on the formation grooves (41), each group of driving rollers (42) comprises two driving rollers, the two driving rollers (42) are arranged in an up-down staggered mode, a plurality of separation grooves are formed in the two driving rollers (42) in a staggered mode, a plurality of groups of bottom rollers (43) are arranged in the formation grooves (41), each group of bottom rollers (43) comprises two rollers which are arranged in an up-down staggered mode, separation grooves (431) are formed in each bottom roller (43), and the separation grooves (431) in the two bottom rollers (43) are arranged in a staggered mode;

after the aluminum foil is cut by the cutting mechanism (2), the formed aluminum foil strips are ordered in the width direction of the aluminum foil, odd aluminum foil strips respectively pass through a separation groove on one driving roller (42) in a group of driving rollers (42) and a separation groove (431) on one bottom roller (43) in a group of bottom rollers (43), and even aluminum foil strips respectively pass through the separation groove on the other driving roller (42) and the separation groove (431) on the other bottom roller (43).

2. The four-sided oxide film fully covered aluminum guide foil production system of claim 1, wherein: the width of the separation groove is equal to the width of the aluminum foil strip, and the width of the separation groove (431) is equal to the width of the aluminum foil strip.

3. The four-sided oxide film fully covered aluminum guide foil production system of claim 1, wherein: negative plates (441) are arranged between two adjacent groups of driving rollers (42) in the formation groove (41), the negative plates (441) are connected with a negative electrode of a direct current power supply, and aluminum foils which are not cut in the unreeling mechanism (1) are connected with a positive electrode of the direct current power supply.

4. The four-sided oxide film fully covered aluminum guide foil production system of claim 1, wherein: the formation mechanism (4) is sequentially provided with a plurality of formation grooves (41), and the voltages in the plurality of formation grooves are sequentially increased.

5. The four-sided oxide film fully covered aluminum guide foil production system of claim 1, wherein: the aluminum foil which is not cut in the unreeling mechanism (1) is the aluminum foil which is subjected to formation or the aluminum foil which is not subjected to formation.

6. The four-sided oxide film fully covered aluminum guide foil production system of claim 1, wherein: the cleaning mechanism (5) comprises a cleaning tank (51), a plurality of groups of driving rollers (42) are also arranged on the cleaning tank (51), a group of bottom rollers (43) are also arranged in the cleaning tank (51), two groups of cleaning plates (52) are arranged in the cleaning tank (51), each group comprises two cleaning plates (52), a plurality of spray heads (521) are respectively arranged on opposite sides of the two cleaning plates (52), odd aluminum foils pass through between the two cleaning plates (52) in one group, and even aluminum foils pass through between the two cleaning plates (52) in the other group.

7. The four-sided oxide film fully covered aluminum guide foil production system of claim 6, wherein: two groups of wiper rods (53) are arranged in the cleaning tank (51), each group of wiper rods (53) comprises two wiper rods, an odd aluminum foil passes through the two wiper rods (53) in one group, an even aluminum foil passes through the two wiper rods (53) in the other group, and the wiper rods (53) are attached to the aluminum foil.

8. The four-sided oxide film fully covered aluminum guide foil production system of claim 1, wherein: the drying mechanism (7) comprises a drying box (71), the drying box (71) is provided with an inlet and an outlet, the drying box (71) is provided with two conveying rollers (72) at the inlet and the outlet, the two conveying rollers (72) are provided with a plurality of isolation grooves in a staggered manner, and an odd aluminum foil and an odd foil respectively pass through the isolation grooves on one conveying roller (72).

9. The four-sided oxide film fully covered aluminum guide foil production system of claim 1, wherein: after the aluminum foil is cut by the cutting mechanism (2), the widths of the formed aluminum foil strips are equal or unequal.