CN112277305B

CN112277305B - Film pasting device for inner shell of aluminum alloy product

Info

Publication number: CN112277305B
Application number: CN202011029638.XA
Authority: CN
Inventors: 高茹
Original assignee: Guangdong Yangdaxin Technology Co ltd
Current assignee: Guangdong Yangdaxin Technology Co ltd
Priority date: 2020-09-27
Filing date: 2020-09-27
Publication date: 2022-11-18
Anticipated expiration: 2040-09-27
Also published as: CN112277305A

Abstract

The invention relates to a film sticking device for an inner shell of an aluminum alloy product. The pad pasting device of aluminum alloy product inner shell is including the transmission frame, the mounting bracket, conveying component, cut membrane module and pad pasting mechanism, be provided with the transmission passageway on the transmission frame, be used for transmitting aluminum alloy product inner shell, the mounting bracket is installed on the lateral wall of transmission frame, conveying component is used for the top of transport film area to aluminum alloy product inner shell, cut membrane module installation on the lateral wall of transmission frame and be used for cutting the membrane area in order to form the diaphragm, pad pasting mechanism includes the pad pasting cylinder, the lift cylinder, locating frame and friction pack, the pad pasting cylinder is installed at the top of mounting bracket and is located the aluminum alloy product inner shell directly over, the lift cylinder is installed on the output shaft of pad pasting cylinder, locating frame is fixed in on the lateral wall of lift cylinder. The film pasting device of the aluminum alloy product inner shell can improve the firmness of film pasting.

Description

Film pasting device for inner shell of aluminum alloy product

Technical Field

The invention relates to a film sticking device for an inner shell of an aluminum alloy product.

Background

The aluminum alloy is an alloy which is based on aluminum and added with a certain amount of other alloying elements, and is one of light metal materials. In addition to the general characteristics of aluminum, aluminum alloys have certain alloy specific characteristics due to the variety and amount of alloying elements added. For example, some aluminum alloy products include iphones and various electronic devices, and the inner case of some aluminum alloy products may be made of plastic or metal, i.e., plastic inner case/metal inner case of aluminum alloy products. Because the inner shell has dustproof and waterproof or insulating demand, consequently can carry out the pad pasting operation in process of production, however, general pad pasting operation is whole pressure equipment the diaphragm on the work piece, causes the diaphragm pine easily to take off, and its attached firmness is not high.

Disclosure of Invention

Therefore, a film pasting device for an inner shell of an aluminum alloy product, which can firmly paste films, is needed.

The utility model provides a pad pasting device of aluminum alloy product inner shell, including the transmission frame, a mounting bracket, the conveying subassembly, cut membrane module and pad pasting mechanism, be provided with transmission channel on the transmission frame, be used for transmitting aluminum alloy product inner shell, the mounting bracket is installed on the lateral wall of transmission frame, the conveying subassembly is used for the top of transport film area to aluminum alloy product inner shell, it installs on the lateral wall of transmission frame and is used for cutting the membrane area in order to form the diaphragm to cut the membrane module, pad pasting mechanism includes the pad pasting cylinder, the lift cylinder, positioning frame and friction subassembly, the pad pasting cylinder is installed at the top of mounting bracket and is located the aluminum alloy product inner shell directly over, the lift cylinder is installed on the output shaft of pad pasting cylinder, positioning frame is fixed in on the lateral wall of lift cylinder, positioning frame's lower extreme horizontal protruding cover is equipped with establishes the platform, cover establishes the platform bottom periphery around being formed with a plurality of boiling hot and establishes the awl post, a plurality of boiling hot and establish the awl post and can install on the bottom surface of establishing the platform telescopically, the centre of cover establishing has seted up the rectangle and has run through the inslot of rectangle, the rectangle is fixed with central station, the bottom of a plurality of lift cylinder is fixed in the bottom of the lift cylinder is equipped with a plurality of flexible awl, the bottom surface of a plurality of the lift cylinder respectively, the lift cylinder is fixed in the lift cylinder, the bottom of a plurality of friction post is fixed in the lift cylinder is fixed in a plurality of flexible awl, the lift cylinder, the bottom of a plurality of flexible awl, the lift cylinder is fixed in the lift cylinder, the bottom surface of every.

In one embodiment, the lifting cylinder is used for driving the plurality of friction columns to move downwards relative to the plurality of conical column cylinders so as to enable the friction inclined rods at the bottom ends of the plurality of friction columns to protrude out of the bottom ends of the plurality of conical column cylinders and abut against the top surface of the inner shell of the aluminum alloy product, so that friction marks are formed through friction, and friction force is increased.

In one embodiment, a circular hole is formed in the conical cylinder, the lower end of each friction column is slidably inserted into the circular hole in the conical cylinder, and the plurality of friction inclined rods at the bottom end of each friction column are accommodated in the circular holes.

In one embodiment, a plurality of jacks are formed in the center platform, the jacks are respectively communicated with the tops of the round holes, and the middle parts of the friction columns are respectively inserted into the jacks in a sliding manner.

In one embodiment, a first power supply is installed on the side wall of the sleeving table, a second power supply is installed on the central table, the first power supply is electrically connected with the plurality of ironing conical columns, and the second power supply is electrically connected with the plurality of conical column tubes.

In one embodiment, the lifting cylinder is further configured to move the plurality of friction columns upwards through the lifting plate, so that each friction column drives the plurality of friction diagonal rods thereon to pass through the circular hole of the conical cylinder until the plurality of friction diagonal rods are received in the insertion holes.

In one embodiment, the film pasting cylinder is used for driving the sleeving table to descend together with the central table so as to utilize the plurality of hot pressing conical columns and the plurality of conical column cylinders to support the diaphragm on the top surface of the inner shell of the aluminum alloy product, and the plurality of hot pressing conical columns and the plurality of conical column cylinders are also used for heating to hot press the diaphragm.

In one embodiment, the film sticking cylinder is further used for continuously driving the sleeving table and the central table to descend so as to force the ironing conical column and the conical column cylinder to contract until the bottom surface of the sleeving table and the bottom surface of the central table abut against the membrane to integrally press and hold the membrane.

In one embodiment, the film cutting assembly comprises a transverse frame, a telescopic cylinder, a positioning plate and a connecting block, the transverse frame is installed on one side, away from the installation frame, of the transmission frame, an L-shaped plate is arranged on the transverse frame in a protruding mode, a cutting groove is formed in the L-shaped plate, and the cutting groove extends to the transmission frame and transversely penetrates through the transmission frame.

In one embodiment, the telescopic cylinder is mounted on the transverse frame and located on one side of the L-shaped plate far away from the transmission frame, the positioning plate is slidably inserted into the cutting groove, the end of the positioning plate is connected with an output shaft of the telescopic cylinder, and the connecting block is fixedly connected with one end, close to the telescopic cylinder, of the positioning plate and is slidably arranged on the L-shaped plate.

When the device is used, the aluminum alloy product inner shell in the transmission channel is stopped and positioned, the film pasting cylinder drives the film pasting assembly to integrally move downwards, the lifting cylinder drives the friction columns to move downwards, the friction inclined rods protrude out of the corresponding conical column cylinders, and then force is continuously applied to the friction inclined rods to incline outwards and pierce the top surface of the aluminum alloy inner shell so as to increase friction force, so that the adhesion binding force of subsequent membranes is increased. Therefore, the friction inclined rod is inclined, so that the friction inclined rod can only be outwards opened after being stressed, and the top surface of the aluminum alloy inner shell is rubbed and punctured by the peripheral surface. And then, the lifting cylinder drives the friction columns to ascend to be separated from the top surface of the inner shell of the aluminum alloy product and enter the center platform. Thereafter the transfer assembly transfers the film strip onto the top surface of the inner shell of the aluminum alloy product. The film cutting assembly cuts the film strip to form a film sheet. The pad pasting cylinder drives the pad pasting subassembly once more and moves down wholly, establish the awl post with a plurality of boiling hot with a plurality of awl column of utilizing and scald and establish the diaphragm, establish the awl post and contract respectively in central station and cover and establish the platform until a plurality of awl column and boiling hot, make on the diaphragm multiple spot melting and atress at this in-process, utilize the central station to press with the bottom surface that scalds and establish the platform after that and hold the diaphragm, so that the diaphragm is whole to press to hold the laminating on the top surface of aluminum alloy product inner shell, then accomplish and cut membrane and pad pasting operation. The cone column is established through setting up boiling hot, thereby can be so that support to establish the fusibility that the cone column can increase the diaphragm in boiling hot on holding the diaphragm, so that the diaphragm scalds through the multiple spot establish connect be fixed in the top surface of aluminum alloy product inner shell on, improve single-point pressure and bonding dynamics, improve the fastness that the diaphragm subsides were established, and scald afterwards and establish cone column and the shrink of a cone column section of thick bamboo, then utilize the bottom surface of central station and the whole pressure of bottom surface of establishing the platform of cover to hold the diaphragm, with whole laminating degree and the roughness that improves the diaphragm.

Drawings

Fig. 1 is a schematic perspective view of a film pasting device for an inner shell of an aluminum alloy product according to an embodiment.

Fig. 2 is a schematic perspective view of another perspective view of the film pasting device for the inner shell of the aluminum alloy product shown in fig. 1.

FIG. 3 is a perspective view of another perspective of the film pasting device for the inner shell of the aluminum alloy product shown in FIG. 1

FIG. 4 is a cross-sectional view of a portion of a friction element according to one embodiment.

Detailed Description

Referring to fig. 1 to 4, a film pasting device for an inner shell of an aluminum alloy product comprises a transmission frame 10, a mounting frame 20, a conveying assembly (not shown), a film cutting assembly 30 and a film pasting mechanism 40, wherein the transmission frame 10 is provided with a conveying channel 15 for conveying the inner shell of the aluminum alloy product, the mounting frame 20 is mounted on a side wall of the transmission frame 10, the conveying assembly is used for conveying a film belt to the upper side of the inner shell of the aluminum alloy product, the film cutting assembly 30 is mounted on the side wall of the transmission frame 10 and is used for cutting the film belt to form a film, the film pasting mechanism 40 comprises a film pasting cylinder 41, a lifting cylinder 42, a positioning frame 43 and a friction assembly 45, the film pasting cylinder 41 is mounted at the top of the mounting frame 20 and is located right above the inner shell of the aluminum alloy product, the lifting cylinder 42 is mounted on an output shaft of the film pasting cylinder 41, the positioning frame 43 is fixed on the side wall of the lifting cylinder 42, the lower end of the positioning frame 43 is transversely provided with a sleeve platform 431 in a protruding manner, the periphery of the bottom of the sleeve platform 431 is formed around a plurality of hot-pressed conical columns 432, the hot-pressed conical columns 432 are telescopically mounted on the bottom surface of the sleeve platform 431, a rectangular through groove 433 is formed in the middle of the sleeve platform 431, a central platform 434 is fixed in the rectangular through groove 433, a plurality of conical column barrels 435 are telescopically arranged at the bottom of the central platform 434, the friction assembly 45 comprises a lifting plate 451 and a plurality of friction columns 452, the top surface of the lifting plate 451 is fixed at the bottom end of the output shaft of the lifting cylinder 42, the friction columns 452 are fixed on the bottom surface of the lifting plate 451 and respectively inserted into the conical column barrels 435, and a plurality of flexible friction rods 453 are convexly arranged at the bottom of each friction column 452.

When the aluminum alloy film sticking device is used, the aluminum alloy product inner shell in the conveying channel 15 is stopped and positioned, the film sticking cylinder 41 drives the film sticking assembly to integrally move downwards, the lifting cylinder 42 drives the plurality of friction columns 452 to move downwards, the plurality of friction inclined rods 453 protrude out of the corresponding conical column tubes 435, and then force is continuously applied, the plurality of friction inclined rods 453 incline outwards and puncture the top surface of the aluminum alloy inner shell to increase friction force, so that the adhesion binding force of a subsequent film is increased. Therefore, the inclined friction bar 453 is inclined so that it can be forced to spread outward only to rub against and pierce the top surface of the aluminum alloy inner shell. Thereafter, lift cylinder 42 causes friction posts 452 to rise away from the top surface of the aluminum alloy product inner shell and into center table 434. Thereafter the transfer assembly transfers the film strip onto the top surface of the inner shell of the aluminum alloy product. The film cutting assembly 30 cuts the film strip to form the film pieces. The film pasting cylinder 41 drives the film pasting assembly to move downwards integrally again, so that the plurality of conical column barrels 435 and the plurality of ironing conical columns 432 are used for ironing the film, until the plurality of conical column barrels 435 and the ironing conical columns 432 are respectively contracted in the central table 434 and the sheathing table 431, in the process, the multiple points on the film are melted and stressed, and then the central table 434 and the bottom surface of the ironing table are used for integrally pressing and holding the film, so that the film is integrally pressed and attached to the top surface of the inner shell of the aluminum alloy product, and then the film cutting and pasting operation is completed. Set up the awl post 432 through the setting scalds, thereby can make to support to hold to scald on the diaphragm and establish the fusibility that the awl post 432 can increase the diaphragm, so that the diaphragm scalds through the multiple spot to establish to connect on being fixed in the top surface of aluminum alloy product inner shell, improve single-point pressure and bonding dynamics, improve the fastness that the diaphragm subsides were established, and scald afterwards and establish awl post 432 and the shrink of a awl post section of thick bamboo 435, then utilize the bottom surface of central platform 434 and the whole diaphragm of pressing of the bottom surface of cover setting platform 431, with the whole laminating degree and the roughness of improvement diaphragm. For example, the transfer assembly is a common technique in the art, and may be, for example, a film roll and a finger clamping cylinder, wherein the two finger clamping cylinders clamp the free end of the film strip, and then pull the free end of the film strip to stretch to the top surface of the inner shell of the aluminum alloy product, and the film roll releases the film strip.

For example, in order to facilitate the accommodation of the plurality of inclined friction rods 453 after piercing the top surface of the aluminum alloy inner shell, the lifting cylinder 42 is used to drive the plurality of friction columns 452 to move downward relative to the plurality of conical column tubes 435, so as to make the inclined friction rods 453 at the bottom ends of the plurality of friction columns 452 protrude out of the bottom ends of the plurality of conical column tubes 435 and abut against the top surface of the aluminum alloy inner shell, so as to form friction marks by friction, thereby increasing the friction force. A circular hole 4355 is formed in the conical cylinder 435, the lower ends of the friction columns 452 are slidably inserted into the circular hole 4355 in the conical cylinder 435, and a plurality of friction diagonal rods 453 at the bottom end of each friction column 452 are received in the circular holes 4355. A plurality of jacks are formed in the center table 434, the jacks are respectively communicated with the tops of the round holes 4355, and the middle portions of the friction columns 452 are respectively inserted into the jacks in a sliding manner. Through set up a plurality of jacks on the central station 434, consequently be convenient for utilize friction post 452 to drive a plurality of friction down tube 453 and accomodate the entering jack, avoid influencing the upwards shrink of follow-up awl column 435.

For example, in order to facilitate the hot setting of friction to form a multi-point hot setting connection, a first power source is installed on the sidewall of the set table 431, a second power source is installed on the center table 434, the first power source is electrically connected with the hot setting conical columns 432, and the second power source is electrically connected with the conical column tubes 435. The first power supply and the second power supply are arranged, so that the conical column 432 and the conical column barrel 435 are convenient to heat and iron. For example, the lifting cylinder 42 is further configured to drive the plurality of friction columns 452 to move upward through the lifting plate 451, so that each friction column 452 drives the plurality of friction diagonal rods 453 thereon to pass through the circular hole of the conical cylinder 435, until the plurality of friction diagonal rods are received in the insertion holes. The film sticking cylinder 41 is used for driving the sheathing table 431 and the central table 434 to descend together so as to utilize a plurality of ironing conical columns 432 and a plurality of conical column tubes 435 to jointly support the film on the top surface of the inner shell of the aluminum alloy product, and the plurality of ironing conical columns 432 and the plurality of conical column tubes 435 are also used for heating to iron the film. The film sticking cylinder 41 is further configured to continuously drive the sleeving table 431 and the central table 434 to descend so as to force the ironing conical column 432 and the conical column barrel 435 to contract until the bottom surface of the sleeving table 431 and the bottom surface of the central table 434 abut against the film, so as to integrally press the film, that is, the ironing conical column 432 and the conical column barrel 435 contract inside the central table 434 and the sleeving table 431. By shrinking the ironing cone column 432 and the cone column barrel 435, the diaphragm can be flattened by the central platform 434 and the bottom surface of the sleeving platform 431. The single-point stress welding is carried out firstly, and then the whole die is flattened, so that the flatness of the film can be guaranteed, and the firmness of the film can be guaranteed. The aligned position of the conical cylinder is just the area rubbed by the friction rod, so that the bonding fixing force is improved.

For example, in order to facilitate cutting of the film strip to form the film, the film cutting assembly 30 includes a transverse frame 31, a telescopic cylinder 32, a positioning plate 33 and a connecting block, the transverse frame 31 is mounted on a side of the transport frame 10 away from the mounting frame 20, an L-shaped plate 312 is protruded on the transverse frame 31, a cutting groove 315 is formed on the L-shaped plate 312, and the cutting groove 315 extends to the transport frame 10 and transversely penetrates through the transport frame 10. The telescopic cylinder 32 is installed on the transverse frame 31 and located on one side of the L-shaped plate 312 far away from the transmission frame 10, the positioning plate 33 is slidably inserted into the cutting groove 315, an end of the positioning plate 33 is connected with an output shaft of the telescopic cylinder 32, and a connecting block is fixedly connected with one end of the positioning plate 33 close to the telescopic cylinder 32 and slidably arranged on the L-shaped plate 312. Through setting up locating plate 33, can fix a position the aluminum alloy product inner shell, can utilize the connecting block to drive two bar blade 37 moreover and remove in place in order to carry out subsequent cutting operation.

For example, it is particularly important that the telescopic cylinder 32 is used to drive the positioning plate 33 to be transversely inserted into the conveying channel 15 of the conveying frame 10 to stop and position the inner shell of the aluminum alloy product in order to smoothly cut the membrane strip to form the membrane. Film cutting assembly 30 still includes film cutting frame 34, rotating electrical machines 35, upset motor 36 and two bar blades 37, film cutting frame 34 is including connecting square column 341 and two L shape cutting board 342, the one end of connecting square column 341 is supported on L shape board 312 with sliding and is fixed in on the connecting block, rotating electrical machines 35 installs in the tip of connecting square column 341 and is in L shape board 312 and keeps away from one side of connecting square column 341, coaxial being fixed with connecting axle 351 on rotating electrical machines 35's the output shaft, connecting axle 351 extends to the one end that L shape board 312 was kept away from to connecting square column 341, the tip of two L shape cutting board 342 all is fixed in on connecting axle 351 and is located the relative both ends of connecting square column 341 respectively. The turning motor 36 is installed at one end of one of the L-shaped knife boards 342 far away from the connecting shaft 351, the end of the output shaft of the turning motor 36 extends to the end of the other L-shaped knife board 342, the output shaft of the turning motor 36 is arranged in parallel with the connecting shaft 351, the ends of the two strip-shaped blades 37 are fixed on the output shaft of the turning motor 36, and the two strip-shaped blades 37 are respectively positioned at the lower sides of the two L-shaped knife boards 342. For example, the length of the strip-shaped blade 37 is greater than the width of the transport channel 15, i.e. the two ends of the strip-shaped blade 37 project beyond the opposite sides of the film strip, respectively. For example, the bottom surface of the iron cone 432 is a circular plane, and the bottom surface of the cone barrel 435 is an annular plane.

When the device is used, the telescopic cylinder 32 drives the positioning plate 33 to move along the cutting groove 315 until the end of the positioning plate 33 abuts against the side wall of the conveying channel 15, so that the positioning plate 33 is used for stopping and positioning the inner shell of the aluminum alloy product in the conveying channel 15, the film cutting assembly 30 also moves to one side of the conveying frame 10, the film sticking cylinder 41 drives the film sticking assembly to integrally move downwards, the lifting cylinder 42 drives the plurality of friction columns 452 to move downwards, the plurality of friction inclined rods 453 protrude out of the corresponding conical column tubes 435, and then the top surface of the inner shell of the aluminum alloy is continuously forced to be punctured by force so as to increase friction force, so that the adhesion bonding force of subsequent films is increased. The lift cylinder 42 then moves the plurality of friction posts 452 up into the center table 434 and out of the plurality of tapered post cylinders 435. The film sticking cylinder 41 drives the film sticking assembly to move upwards integrally so as to avoid the film cutting frame 34. Thereafter the transfer assembly transfers the film strip onto the top surface of the inner shell of the aluminum alloy product. The rotating motor 35 drives the two L-shaped knife boards 342 to overturn right above the transmission channel 15 through the connecting shaft 351, and the overturning motor 36 drives the two strip-shaped blades 37 to rotate so as to start to cut the film strip from one side adjacent to the L-shaped board 312 by using the strip-shaped blades 37, so that the film materials on the two sides of the aluminum alloy inner shell are all cut off, and then the film sheet is formed. Since both sides of the strip-shaped blade 37 are located outside the opposite sides of the film web, the strip-shaped blade 37 after deflection, i.e. rotation, is sufficient to completely cut off the film web. Then, the reverse motor 36 reversely drives the two bar blades 37 to return to the original positions, and then the rotary motor 35 drives the two L-shaped knife plates 342 to reverse away from the conveyance path 15. Afterwards, the film pasting cylinder 41 drives the film pasting assembly to move down integrally again, so that the plurality of conical column barrels 435 and the plurality of hot-pressed conical columns 432 are used for hot-pressing the film, until the plurality of conical column barrels 435 and the hot-pressed conical columns 432 shrink into the central table 434 and the sheathing table 431 respectively, and then the central table 434 and the bottom surface of the hot-pressed table are used for pressing and holding the film, so that the film is integrally pressed and attached to the top surface of the inner shell of the aluminum alloy product, and then the film cutting and pasting operation is completed. For example, the ironing taper cylinder 432 may be installed inside the bottom surface of the sleeving platform 431 by a compression spring, and the taper cylinder 435 may be installed inside the bottom surface of the central platform 434 by a compression spring. For example, a plurality of friction burrs are provided on the circumferential surface of each friction diagonal 453.

By arranging the film cutting assembly 30, the film cutting frame 34 can be driven to be adjacent to the transmission frame 10 while the positioning plate 33 is driven to be inserted into the transmission channel 15 for stopping and positioning, so that two purposes are achieved at one time. And the setting of upset motor 36 and two bar blades 37 can be comparatively conveniently cut from one side of membrane area to the opposite side gradually, has reduced the resistance in whole cutting membrane area, improves the smooth and easy degree of cutting the membrane. And through setting up first power and second power, thereby can make elasticity support to hold boiling hot on the diaphragm and establish the fusibility that awl post 432 and awl post section of thick bamboo 435 can increase the diaphragm, so that the diaphragm scalds through the multiple spot connection and establishes on the top surface that is fixed in the aluminum alloy product inner shell, improve single-point pressure and bonding dynamics, improve the fastness that the diaphragm subsides were established, and scald afterwards and establish awl post 432 and the shrink of awl post section of thick bamboo 435, then utilize the bottom surface of central station 434 and the whole pressure of the bottom surface of cover platform 431 to hold the diaphragm, with whole laminating degree and the roughness that improves the diaphragm. FIG. 4 is a cross-sectional view of a portion of a friction element according to an embodiment, wherein the taper of the tapered barrel is not shown.

Claims

1. A film sticking device for an inner shell of an aluminum alloy product is characterized by comprising a transmission frame, a mounting frame, a conveying assembly, a film cutting assembly and a film sticking mechanism, wherein the transmission frame is provided with a transmission channel for transmitting the inner shell of the aluminum alloy product, the mounting frame is arranged on the side wall of the transmission frame, the conveying assembly is used for conveying a film belt to the upper part of the inner shell of the aluminum alloy product, the film cutting assembly is arranged on the side wall of the transmission frame and used for cutting the film belt to form a film sheet, the film sticking mechanism comprises a film sticking cylinder, a lifting cylinder, a positioning frame and a friction assembly, the film sticking cylinder is arranged at the top of the mounting frame and is positioned right above the inner shell of the aluminum alloy product, the lifting cylinder is arranged on an output shaft of the film sticking cylinder, the positioning frame is fixed on the side wall of the lifting cylinder, the lower end of the positioning frame is transversely provided with a sleeve station in a protruding manner, the periphery of the bottom of the sleeve station is surrounded by a plurality of hot-setting conical columns, the hot-setting conical columns can be telescopically mounted on the bottom surface of the sleeve station, a rectangular through groove is formed in the middle of the sleeve station, a central station is fixed in the rectangular through groove, a plurality of conical column barrels can be telescopically arranged at the bottom of the central station, the friction assembly comprises a lifting plate and a plurality of friction columns, the top surface of the lifting plate is fixed at the bottom end of an output shaft of the lifting cylinder, the friction columns are fixed on the bottom surface of the lifting plate and are respectively inserted into the conical column barrels, and a plurality of flexible friction inclined rods are arranged at the bottom of each friction column in a protruding manner; the film cutting assembly comprises a transverse frame, a telescopic cylinder, a positioning plate and a connecting block, the transverse frame is installed on one side, away from the installation frame, of the transmission frame, an L-shaped plate is arranged on the transverse frame in a protruding mode, a cutting groove is formed in the L-shaped plate and extends to the transmission frame and transversely penetrates through the transmission frame, the telescopic cylinder is installed on the transverse frame and is located on one side, away from the transmission frame, of the L-shaped plate, the positioning plate is inserted into the cutting groove in a sliding mode, the end portion of the positioning plate is connected with an output shaft of the telescopic cylinder, the connecting block is fixedly connected with one end, close to the telescopic cylinder, of the positioning plate and is arranged on the L-shaped plate in a sliding mode, an inner shell of an aluminum alloy product is positioned through the positioning plate, and the connecting block is used for driving the two strip-shaped blades to move in place to execute subsequent cutting operation;

the telescopic cylinder is used for driving the positioning plate to be transversely inserted into a transmission channel of the transmission frame, the aluminum alloy product inner shell is positioned by the stop, the film cutting assembly further comprises a film cutting frame, a rotating motor, a turnover motor and two strip-shaped blades, the film cutting frame comprises a connecting square column and two L-shaped cutter plates, one end of the connecting square column is slidably supported on the L-shaped plate and is fixed on the connecting block, the rotating motor is mounted at the end part of the connecting square column and is positioned at one side, away from the connecting square column, of the L-shaped plate, a connecting shaft is coaxially fixed on an output shaft of the rotating motor and extends to one end, away from the L-shaped plate, of the connecting square column, the end parts of the two L-shaped cutter plates are fixed on the connecting shaft and are respectively positioned at the two opposite ends of the connecting square column, the turnover motor is mounted at one end, away from the connecting shaft, of the output shaft of the turnover motor extends to the end part of the other L-shaped cutter plate, the output shaft of the turnover motor is arranged in parallel to the end parts of the two strip-shaped cutter plates, the two ends of the two strip-shaped cutter plates are respectively fixed on the output shaft of the turnover motor, the two strip-shaped cutter plates are respectively positioned at the lower sides of the two L-shaped cutter plates, the bottom of the conical cylinder, the conical surface of the conical cylinder is circular plane, and the conical cylinder.

2. The film sticking device for the inner shell of the aluminum alloy product as recited in claim 1, wherein the lifting cylinder is used for driving the plurality of friction columns to move downwards relative to the plurality of conical column tubes so as to enable the friction inclined rods at the bottom ends of the plurality of friction columns to protrude out of the bottom ends of the plurality of conical column tubes and to be abutted against the top surface of the inner shell of the aluminum alloy product, so as to form friction marks by friction to increase friction force.

3. A film sticking device for an inner shell of an aluminum alloy product as recited in claim 2, wherein a circular hole is formed in the conical cylinder, the lower end of the friction cylinder is slidably inserted into the circular hole in the conical cylinder, and the plurality of friction diagonal rods at the bottom end of each friction cylinder are received in the circular holes.

4. A film sticking device for an inner shell of an aluminum alloy product according to claim 3, wherein a plurality of insertion holes are formed in the center table, the insertion holes are respectively communicated with the tops of the circular holes, and the middle parts of the friction columns are respectively inserted into the insertion holes in a sliding manner.

5. A film sticking device for an inner shell of an aluminum alloy product according to claim 4, wherein a first power supply is installed on the side wall of the sleeving table, a second power supply is installed on the central table, the first power supply is electrically connected with the plurality of ironing conical columns, and the second power supply is electrically connected with the plurality of conical column tubes.

6. A film sticking device for an inner shell of an aluminum alloy product according to claim 5, wherein the lifting cylinder is further used for driving the plurality of friction columns to move upwards through the lifting plate, so that each friction column drives the plurality of friction inclined rods thereon to pass through the circular holes of the conical column barrel until the plurality of friction inclined rods are received in the insertion holes.

7. A film sticking device for an inner shell of an aluminum alloy product according to claim 6, wherein the film sticking cylinder is used for driving the sleeving table to descend together with the central table so as to utilize a plurality of hot set conical columns and a plurality of conical column sleeves to jointly press the film sheet against the top surface of the inner shell of the aluminum alloy product, and the plurality of hot set conical columns and the plurality of conical column sleeves are further used for heating to hot set the film sheet.

8. A film sticking device for an inner shell of an aluminum alloy product according to claim 7, wherein the film sticking cylinder is further used for continuously driving the sleeving table and the central table to descend so as to force the ironing conical columns and the conical column cylinders to shrink until the bottom surfaces of the sleeving table and the central table are abutted against the membrane so as to integrally press the membrane.