CN219097080U

CN219097080U - Film sticking device

Info

Publication number: CN219097080U
Application number: CN202223388939.9U
Authority: CN
Inventors: 王有德; 王志宾; 高天虎; 胡宏明
Original assignee: Fulian Yuzhan Technology Shenzhen Co Ltd
Current assignee: Fulian Yuzhan Technology Shenzhen Co Ltd
Priority date: 2022-12-16
Filing date: 2022-12-16
Publication date: 2023-05-30
Anticipated expiration: 2032-12-16

Abstract

The utility model provides a film sticking device which comprises a transmission mechanism, a cutting mechanism, an adsorption mechanism, a folding handle mechanism and a supporting mechanism. The conveying mechanism comprises a conveying support, a feeding part and a receiving part, wherein the feeding part is connected with the conveying support and used for loading a base film, the receiving part is connected with the conveying support and is arranged at intervals with the feeding part and used for driving the base film to move along a first direction, the cutting mechanism is used for cutting the base film between the feeding part and the receiving part to form a cutting film, the cutting film comprises a main body part and a laminating part connected with the main body part, the adsorbing mechanism is used for adsorbing and driving the main body part to move so as to drive the cutting film to move from the base film to a laminating position, the handle folding mechanism is arranged between the base film and the laminating position and used for propping against the laminating part to the main body part to form a finished film, and the supporting mechanism is used for bearing and driving a product to move to the laminating position and is also used for driving the finished film to laminate to the product. The film pasting device has low labor intensity, simplifies the operation process of finished films and improves the film pasting efficiency.

Description

Film sticking device

Technical Field

The utility model relates to the technical field of film sticking, in particular to a film sticking device.

Background

The product film is generally composed of a main body part and a bonding part, wherein the bonding part is adhered to the main body part, so that the product film is conveniently transferred through the bonding part, when the product film is bonded to a product, the product is generally required to be positioned first, then the product film is manually taken down from the base paper, and finally the product film is adhered to the product. However, the film sticking operation with the base paper is complicated, the labor intensity is high, and the film sticking efficiency is low.

Disclosure of Invention

In view of the foregoing, it is necessary to provide a film laminating apparatus to improve the film laminating efficiency.

The embodiment of the utility model provides a film sticking device, which is used for sticking a finished film to a product, and comprises the following components:

the conveying mechanism comprises a conveying support, a feeding piece and a receiving piece, wherein the feeding piece is connected with the conveying support and used for loading the bottom film, and the receiving piece is connected with the conveying support and is arranged with the feeding piece at intervals along a first direction and used for receiving and driving the bottom film to move along the first direction;

the cutting mechanism is used for cutting the bottom film between the feeding piece and the receiving piece to form a cutting film, and the cutting film comprises a main body part and a fitting part connected with the main body part;

the adsorption mechanism is used for adsorbing and driving the main body part to move so as to separate the cutting film from the bottom film, and is also used for driving the cutting film to move from the bottom film to a film pasting position;

the folding handle mechanism is arranged between the bottom film and the film pasting position and used for propping the pasting part to be pasted to the main body part so as to form the finished film;

the supporting mechanism is used for bearing and driving the product to move to the film pasting position; wherein,,

the adsorption mechanism is also used for driving the finished film to be attached to a product positioned at the film attaching position.

When the film pasting device is operated, firstly, the receiving piece drives the bottom film to move along the first direction by the feeding piece, the cutting mechanism cuts the bottom film at the target position to form a cutting film comprising a main body part and a pasting part, the adsorption mechanism adsorbs the main body part and drives the cutting film to be separated from the bottom film, then, the folding handle mechanism props against the pasting part to be pasted to the main body part to form a finished film, and finally, the adsorption mechanism adsorbs the main body part to drive the finished film to move to the film pasting position and complete pasting of the finished film. Therefore, the forming of the cutting film, the separation of the cutting film and the bottom film, the forming of the finished film and the attaching operation of the finished film are continuous, the labor intensity is low, and the operation process of the finished film is simplified, so that the film attaching efficiency is improved.

In some embodiments, the cutting mechanism comprises:

a carrier assembly;

the laser piece is connected with the bearing assembly and used for cutting the bottom film between the feeding piece and the receiving piece to form the cutting film; wherein,,

the laminating portion of cutting membrane breaks away from the carrier film, the main part of cutting membrane is connected the carrier film.

In some embodiments, the load bearing assembly comprises:

the first cutting driving piece is connected with the laser piece and used for driving the laser piece to move along the first direction;

and the second cutting driving piece is connected with the first cutting driving piece and is used for driving the first cutting driving piece to move along a second direction perpendicular to the first direction.

In some embodiments, the adsorption mechanism comprises:

an adsorbing member for adsorbing the main body;

and the transfer driving piece is connected with the absorption piece and is used for driving the absorption piece to drive the cutting film to prop against the folding handle mechanism and driving the absorption piece to prop against the finished film to the film pasting position.

In some embodiments, the film sticking position is located at the lower side of the bottom film, the folding handle mechanism is used for propping against the attaching part along the first direction to attach to the main body part so as to form the finished film, and the transferring driving part is used for driving the adsorbing part to sequentially drive the cutting film to separate from the bottom film along the second direction and attach the finished film to a product located at the film sticking position.

In some embodiments, the adsorption mechanism further comprises:

and the rotary driving piece is connected with the transfer driving piece and is used for driving the transfer driving piece to drive the adsorption piece to rotate.

In some embodiments, the adsorption mechanism further comprises:

the adsorption bracket is connected with the transfer driving piece;

and the sliding driving piece is connected with the adsorption bracket and used for driving the adsorption bracket to slide along the first direction.

In some embodiments, the folding handle mechanism comprises:

the abutting piece is used for abutting the abutting part to be attached to the main body part;

and the folding driving assembly is connected with the supporting piece and used for driving the supporting piece to move along the first direction.

In some embodiments, the supporting member extends along a third direction perpendicular to the first direction, one end of the supporting member is slidably connected with the transmission bracket along the first direction, and the folding driving assembly is connected with the other end of the supporting member and the transmission bracket.

In some embodiments, the folding driving assembly includes a folding driving member, a driving wheel, a driven wheel, and a transmission belt, where the folding driving member is disposed on the transmission support and connected to the driving wheel, the driven wheel is connected to the transmission support and is disposed along the first direction at intervals with the driving wheel, the transmission belt is rollingly connected to the driving wheel and the driven wheel, one end of the supporting member is connected to the transmission belt, and the other end of the supporting member is slidingly connected to the transmission support along the first direction.

In some embodiments, the film sticking device further comprises:

an electrostatic bracket slidably connected to the transport bracket along the first direction;

the plasma rod is connected with the electrostatic bracket and is used for eliminating the static electricity of the bottom film;

and the electrostatic driving piece is connected with the transmission bracket and the electrostatic bracket and is used for driving the electrostatic bracket to slide along the transmission bracket.

In some embodiments, the film sticking device is further provided with a feeding level, the supporting mechanism comprises a supporting piece and a rotation driving piece, the supporting piece is used for bearing the product, and the rotation driving piece is connected with the supporting piece and used for driving the supporting piece to rotate between the feeding level and the film sticking level.

Drawings

Fig. 1 is a schematic view of a dicing film according to an embodiment of the utility model.

FIG. 2 is a schematic diagram of the structure of a finished film according to an embodiment of the present utility model.

Fig. 3 is a schematic structural diagram of a film sticking device and a base film according to an embodiment of the present utility model.

Fig. 4 is another angular schematic view of a portion of the structure of fig. 3.

Fig. 5 is a schematic structural view of the adsorption mechanism in fig. 3.

Fig. 6 is an enlarged schematic view of the area a in fig. 3.

Fig. 7 is a schematic structural view of the supporting mechanism in fig. 3.

Description of the main reference signs

Base film 10

Bonding portion 101

Body portion 102

Cutting film 11

Finished film 12

Film laminating apparatus 20

Film laminating station 20a

Feeding level 20b

Transport mechanism 21

Transmission support 211

Feed 212

Receiving element 213

Cutting mechanism 22

Carrier assembly 221

First cutting drive 2211

Second cutting drive 2212

Laser piece 222

Adsorption mechanism 23

Suction member 231

Transfer driving member 232

Adsorption bracket 233

Slide drive 234

Folding handle mechanism 24

Holding piece 241

Folding drive assembly 242

Folding driving piece 2421

Driving wheel 2422

Driven wheel 2423

Conveyor belt 2424

Supporting mechanism 25

Support member 251

Rotation driving piece 252

Electrostatic support 26

Plasma rod 27

Electrostatic actuator 28

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein the same or similar reference numerals refer to the same or similar elements or elements having the same or similar functions throughout. The embodiments described below by referring to the drawings are exemplary only for explaining the present utility model and are not to be construed as limiting the present utility model.

In the description of the present utility model, 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 utility model and simplifying the description, and do not indicate or imply that the device or element 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 utility model. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more of the described features. In the description of the present utility model, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically connected, electrically connected or can be communicated with each other; can be directly connected or indirectly connected through an intermediate medium, and can be communicated with the inside of two elements or the interaction relationship of the two elements. The specific meaning of the above terms in the present utility model can be understood by those of ordinary skill in the art according to the specific circumstances.

The embodiments of the present utility model will be described in detail below with reference to the accompanying drawings.

Referring to fig. 1 and 2, fig. 1 and 2 show a cut film 11 and a final film 12, respectively, formed after a base film 10 is processed, and each of the cut film 11 and the final film 12 includes a bonding portion 101 and a main body portion 102. Specifically, the base film 10 has a bonding surface and a smooth surface which are oppositely disposed, the structure of the cutting film 11 is that one end of the bonding portion 101 is connected to one end of the main body 102, the other end of the bonding portion 101 is separated from the main body 102, the structure of the product film 12 is that the bonding surface of the bonding portion 101 is bonded to a part of the bonding surface of the main body 102, so that in the product film 12, the upper and lower surfaces of the bonding area where the bonding portion 101 and the main body 102 are bonded are smooth surfaces, and the formed product film 12 can be bonded to a product through other parts of the bonding surface on the main body 102, for example: the product can be a protective film attached to the electronic equipment, and after the electronic equipment is processed, the protective film can be separated from the electronic equipment by driving the attaching part 101 and the main body part 102 to attach to each other.

For convenience of description, in fig. 3 and fig. 4, a three-dimensional coordinate system is added, specifically, a direction in which the X axis is located is a first direction, that is, a setting direction from the feeding member 212 to the receiving member 213, a direction in which the Y axis is located is a third direction, that is, an extending direction of the abutting member 241, and a direction in which the Z axis is located is a second direction, that is, a vertical direction. Wherein, X axis, Y axis, Z axis are two by two perpendicular.

Referring to fig. 3 and 4, an embodiment of the present utility model provides a film laminating apparatus 20, which includes a conveying mechanism 21, a cutting mechanism 22, an adsorbing mechanism 23, a folding handle mechanism 24 and a supporting mechanism 25, and is used for laminating a finished film 12 to a product. Illustratively, the product may be a cell phone screen, a glass substrate, or the like.

Specifically, the smooth surface of the carrier film 10 is provided corresponding to the cutting mechanism 22, and when the cutting mechanism 22 processes the carrier film 10, the smooth surface of the carrier film 10 is processed so that the cut film 11 is formed and the adhesive surface in the finished film 12 is bonded to the product.

In some embodiments, the conveying mechanism 21 includes a conveying support 211, a feeding member 212, and a receiving member 213, where the feeding member 212 is connected to the conveying support 211 and is used for loading the carrier film 10, and the receiving member 213 is connected to the conveying support 211 and is spaced from the feeding member 212 along a first direction, and is used for receiving and driving the carrier film 10 to move along the first direction; the cutting mechanism 22 is for cutting the base film 10 between the supply member 212 and the take-up member 213 to form a cut film 11; the adsorption mechanism 23 is used for adsorbing and driving the main body part 102 to move so as to separate the cutting film 11 from the base film 10, and the adsorption mechanism 23 is also used for driving the cutting film 11 to move from the base film 10 to the film pasting position 20a; the handle folding mechanism 24 is arranged between the base film 10 and the film pasting position 20a and is used for propping against the pasting part 101 to be pasted to the main body part 102 so as to form a finished film 12; the supporting mechanism 25 is used for carrying and driving the product to move to the film pasting position 20a, and the adsorbing mechanism 23 is also used for driving the finished film 12 to be pasted to the product at the film pasting position 20 a. In this embodiment, the base film 10 is rolled, and is led out from the feeding member 212 and collected to the receiving member 213, wherein the feeding member 212 and the receiving member 213 may be rolling wheels.

When the film laminating apparatus 20 is operated, firstly, the receiving member 213 drives the base film 10 to move along the first direction from the feeding member 212, the cutting mechanism 22 cuts the base film 10 at the target position to form the cut film 11, the adsorbing mechanism 23 adsorbs the main body portion 102 and drives the cut film 11 to separate from the base film 10, then the folding handle mechanism 24 abuts against the attaching portion 101 and attaches to the main body portion 102 to form the finished film 12, and finally, the adsorbing mechanism 23 adsorbs the main body portion 102 to drive the finished film 12 to move to the film attaching position 20a and complete the attachment of the finished film 12 to the product. Therefore, the forming of the cutting film 11, the separation of the cutting film 11 and the base film 10, the forming of the finished film 12 and the attaching operation of the finished film 12 are continuous, the labor intensity is low, and the film attaching device 20 simplifies the operation process of the finished film 12, thereby improving the film attaching efficiency.

Referring to fig. 3, in some embodiments, the cutting mechanism 22 includes a carrier 221 and a laser 222. The laser piece 222 is connected to the carrier component 221, and is used for cutting the base film 10 between the feeding piece 212 and the receiving piece 213 to form a cut film 11, the attaching portion 101 of the cut film 11 is separated from the base film 10, and the main body portion 102 of the cut film 11 is connected to the base film 10.

Therefore, the laser piece 222 is used for cutting the base film 10, the cutting efficiency and accuracy are high, the laser piece 222 is connected to the bearing component 221, and the laser piece 222 and the bearing component can synchronously move under the action of external force, so that the position of the cutting mechanism 22 relative to the transmission mechanism 21 can be conveniently adjusted.

In some embodiments, the carrier assembly 221 includes a first cutting drive 2211 and a second cutting drive 2212. The first cutting driving member 2211 is connected to the laser member 222 for driving the laser member 222 to move along a first direction so as to be convenient for adjusting the cutting position of the laser member 222 on the carrier film 10, and the second cutting driving member 2212 is connected to the first cutting driving member 2211 for driving the first cutting driving member 2211 to move along a second direction so as to be convenient for adjusting the distance between the laser member 222 and the carrier film 10 in the vertical direction. Illustratively, the first and second cutting drives 2211 and 2212 may each be ball screws or linear motors.

Therefore, the first cutting driving member 2211 and the second cutting driving member 2212 can respectively drive the laser member 222 to move in the first direction and the vertical direction relative to the base film, adjust the position of the laser member 222 in the first direction and the vertical direction relative to the base film 10, and increase the cutting range of the laser member 222.

Referring to fig. 5, in some embodiments, the suction mechanism 23 includes a suction member 231 and a transfer driving member 232. The absorbing member 231 is used for absorbing the main body 102, the transferring driving member 232 is connected with the absorbing member 231 and used for driving the absorbing member 231 to drive the attaching portion 101 of the cutting film 11 to abut against the folding handle mechanism 24, so that the attaching portion 101 attaches to the main body 102 to form the finished film 12, and the transferring driving member 232 is also used for driving the absorbing member 231 to abut against the finished film 12 to the film attaching position 20a, so that the finished film 12 attaches to a product located in the film attaching position 20a, and the folding handle mechanism is simple in structure and convenient to operate. Illustratively, the transfer driving member 232 may be a linear motor, and the adsorption member 231 may be a vacuum adsorber.

In some embodiments, the film attaching position 20a is located at the lower side of the base film 10, the folding handle mechanism 24 is used to abut against the attaching portion 101 to attach to the main body portion 102 along the first direction to form the product film 12, and the transferring driving member 232 is used to drive the adsorbing member 231 to sequentially drive the cutting film 11 to detach from the base film 10 along the second direction and attach the product film 12 to the product located at the film attaching position 20 a. Illustratively, the transfer drive 232 may be a linear motor.

Accordingly, the base film 10, the folding handle mechanism 24 and the film attaching position 20a are sequentially arranged in the second direction, so that the formation of the cut film 11, the formation of the finished film 12 and the attaching operation of the finished film 12 are continuous, thereby improving the film attaching efficiency.

It should be noted that, the film sticking position 20a located on the lower side of the base film 10 includes two forms:

(1) The product on the film sticking position 20a corresponds to the cut film 11 formed on the base film 10 in the second direction. In operation, the transfer driving member 232 drives the adsorbing member 231 to move to the main body 102 and adsorb the main body 102 through the adsorbing member 231, then the transfer driving member 232 drives the adsorbing member 231 to drive the cutting film 11 to move downward to separate from the base film 10 and abut against the attaching portion 101 to attach to the main body 102 through the folding handle mechanism 24 to form the product film 12, and finally, the transfer driving member 232 drives the adsorbing member 231 to drive the product film 12 to move downward continuously so that the product film 12 abuts against and attaches to the product at the film attaching position 20 a.

(2) The product on the film-attaching position 20a is displaced from the dicing film 11 formed on the base film 10 in the second direction. In operation, the transfer driving member 232 drives the adsorbing member 231 to move to the main body 102 and adsorb the main body 102 through the adsorbing member 231, then the transfer driving member 232 drives the adsorbing member 231 to drive the cutting film 11 to move upwards to separate from the base film 10, and the transfer driving member 232 is driven to rotate manually or through a rotation driving member described below, so that the cutting film 11 adsorbed by the adsorbing member 231 corresponds to a product at the film attaching position 20a, then the folding handle mechanism 24 abuts against the attaching portion 101 to attach to the main body 102 to form the finished film 12, and finally the transfer driving member 232 drives the adsorbing member 231 to drive the finished film 12 to move downwards continuously so that the finished film 12 abuts against and attaches to the product at the film attaching position 20 a.

In some embodiments, the adsorption mechanism 23 further includes a rotary drive (not shown). The rotation driving member is connected to the transfer driving member 232, and is used for driving the transfer driving member 232 to drive the suction member 231 to rotate, so as to realize the second form that the film laminating position 20a is located in the lower side of the base film 10. The rotary drive may be a rotary motor, for example.

Referring to fig. 5, in some embodiments, the adsorption mechanism 23 further includes an adsorption bracket 233 and a sliding driving member 234. The adsorption bracket 233 is connected with the transfer driving member 232, the sliding driving member 234 is connected with the adsorption bracket 233, and the sliding driving member 234 is used for driving the adsorption bracket 233 to slide along the first direction, so that the adsorption member 231 can adsorb the cutting films 11 formed on the carrier film 10 at a plurality of positions in the conveying direction of the carrier film 10, and the application range of the adsorption mechanism 23 is enlarged. In addition, the sliding driving member 234 drives the adsorbing bracket 233 to slide along the first direction, so that the adsorbing member 231 can avoid the laser member 222 in the cutting mechanism 22, and collision between the adsorbing member 231 and the laser member 222 can be avoided. Illustratively, the sliding drive 234 may be a linear cylinder or a linear motor.

Referring to fig. 4, in some embodiments, the folding handle mechanism 24 includes a supporting member 241 and a folding driving assembly 242. The folding driving component 242 is connected with the abutting component 241 and is used for driving the abutting component 241 to move along a first direction, so that the abutting component 241 abuts against the attaching portion 101 to attach to the main body portion 102, and the folding driving component is simple in structure and convenient to operate. For example, the folding driving assembly 242 may be disposed below the transmission mechanism 21, and the folding handle mechanism 24 and the transmission mechanism 21 are separated from each other, so that the assembly process of the film laminating device 20 can be simplified, the assembly efficiency can be improved, and the folding driving assembly 242 may also be connected to the transmission bracket 211, and form a synchronous movement mechanism with the transmission mechanism 21, so as to facilitate the whole transfer of the film laminating device 20.

In some embodiments, the abutting piece 241 extends along the third direction, one end of the abutting piece 241 is slidably connected to the transmission bracket 211 along the first direction, and the folding driving component 242 is connected to the other end of the abutting piece 241 and the transmission bracket 211, so that the folding handle mechanism 24 and the transmission mechanism 21 move synchronously. In this embodiment, the supporting member 241 is elongated.

In some embodiments, the folding driving assembly 242 includes a folding driving member 2421, a driving wheel 2422, a driven wheel 2423 and a transmission belt 2424, wherein the folding driving member 2421 is disposed on the transmission frame 211 and connected to the driving wheel 2422, the driven wheel 2423 is connected to the transmission frame 211 and is spaced apart from the driving wheel 2422 along a first direction, the transmission belt 2424 is in rolling connection with the driving wheel 2422 and the driven wheel 2423, one end of the abutting member 241 is connected to the transmission belt 2424, and the other end of the abutting member 241 is in sliding connection with the transmission frame 211 along the first direction. Illustratively, the flap driver 2421 may be a motor.

During operation, the adsorption mechanism 23 adsorbs and drives the cutting film 11 to move between the bottom film 10 and the film pasting position 20a, and then the folding driving member 2421 drives the driving wheel 2422 to drive the transmission belt 2424 to rotate, so that the transmission belt 2424 drives the abutting member 241 to abut against the abutting part 101 along the first direction to abut against the main body part 102 to form the finished film 12, thereby realizing automatic formation of the cutting film 11 to the finished film 12, and having simple structure and low manufacturing cost.

Referring to fig. 6, in some embodiments, the film laminating apparatus 20 further includes an electrostatic support 26, a plasma rod 27, and an electrostatic driving member 28. The electrostatic support 26 is slidably connected with the transmission support 211 along the first direction, the plasma rod 27 is connected with the electrostatic support 26 for eliminating static electricity of the base film 10, bad lamination of the lamination part 101 and the main body part 102 in the formed cutting film 11 is avoided, and the electrostatic driving piece 28 is connected with the transmission support 211 and the electrostatic support 26 for driving the electrostatic support 26 to slide along the transmission support 211, so that the action range of the plasma rod 27 is improved.

Referring to fig. 7, in some embodiments, the film laminating apparatus 20 further includes a loading level 20b, the supporting mechanism 25 includes a supporting member 251 and a rotation driving member 252, the supporting member 251 is used for carrying a product, and the rotation driving member 252 is connected to the supporting member 251 and is used for driving the supporting member 251 to rotate between the loading level 20b and the film laminating level 20 a. Illustratively, the rotary drive 252 may be a rotary cylinder.

In operation, the product to be processed is transferred to the upper material level 20b by an external transfer mechanism (e.g. a manipulator), then the support member 251 is driven by the rotary driving member 252 to drive the product to be processed to rotate from the upper material level 20b to the film pasting position 20a, the finished film 12 is pasted to the product to be processed by the film pasting device 20, and finally the processed product is driven by the rotary driving member 252 to rotate from the film pasting position 20a to the upper material level 20b by the support member 251, and the processed product is transferred from the upper material level 20b by an external transfer mechanism (e.g. a manipulator). The synchronous operation of the product to be processed and the product after processing can be realized, thereby improving the film pasting efficiency of the film pasting device 20.

Here, taking the product on the film sticking position 20a and the cut film 11 formed on the base film 10 corresponding in the second direction as an example, the working process of the film sticking device 20 is described as follows:

firstly, a product to be processed is transferred to the feeding position 20b by an external transfer mechanism (such as a mechanical arm), the rotary driving piece 252 drives the supporting piece 251 to drive the product to be processed to rotate from the feeding position 20b to the film pasting position 20a, and in the process, the receiving piece 213 drives the bottom film 10 to move along a first direction;

next, the laser 222 is driven by the first cutting driving member 2211 and the second cutting driving member 2212 to move to a target position (a preset height from the carrier film), and cuts the carrier film 10 to form a cut film 11, and in this process, the receiving member 213 does not drive the carrier film 10 to move, so that the carrier film 10 is in a static state;

then, the transfer driving member 232 drives the absorbing member 231 to drive the cutting film 11 to move downwards so as to separate from the base film 10, the folding driving member 242 drives the abutting member 241 to abut against the abutting portion 101 along the first direction and abut against the main body portion 102 so as to form the finished film 12, the transfer driving member 232 drives the absorbing member 231 to drive the finished film 12 to move downwards so as to abut against and abut against the finished film 12 on the product at the film abutting position 20a, and in the process, the receiving member 213 still does not drive the base film 10 to move so that the base film 10 is still in a static state;

finally, the transfer driving member 232 drives the suction member 231 to move upwards above the base film 10, and the rotation driving member 252 drives the supporting member 251 to drive the product attached with the finished film 12 to rotate from the film attaching position 20a to the feeding position 20b.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Finally, it should be noted that the above-mentioned embodiments are merely for illustrating the technical solution of the present utility model and not for limiting the same, and although the present utility model has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made to the technical solution of the present utility model without departing from the spirit and scope of the technical solution of the present utility model.

Claims

1. A film laminating apparatus for attaching a finished film to a product, the film laminating apparatus comprising:

2. The film laminating apparatus of claim 1, wherein said cutting mechanism comprises:

a carrier assembly;

3. The film laminating apparatus of claim 2, wherein said carrier assembly comprises:

4. The film laminating apparatus as set forth in claim 1, wherein said adsorption mechanism includes:

an adsorbing member for adsorbing the main body;

5. A film sticking apparatus according to claim 4, wherein,

the film sticking position is positioned at the lower side of the bottom film;

the folding handle mechanism is used for propping the attaching part to attach to the main body part along the first direction so as to form the finished film;

the transfer driving piece is used for driving the adsorption piece to sequentially drive the cutting film to separate from the bottom film along the second direction and attach the finished film to a product positioned at the film attaching position.

6. The film laminating apparatus of claim 5, wherein said adsorption mechanism further comprises:

7. The film laminating apparatus of claim 4, wherein said adsorption mechanism further comprises:

the adsorption bracket is connected with the transfer driving piece;

8. The film laminating apparatus as set forth in claim 1, wherein said folding handle mechanism includes:

9. A film sticking apparatus according to claim 8, wherein,

the supporting piece is arranged in an extending mode along a third direction perpendicular to the first direction;

one end of the supporting piece is connected with the transmission bracket in a sliding manner along the first direction;

the folding driving assembly is connected with the other end of the supporting piece and the transmission support.

10. A film sticking apparatus according to claim 9, wherein,

the folding driving assembly comprises a folding driving piece, a driving wheel, a driven wheel and a transmission belt;

the folding driving piece is arranged on the transmission support and connected with the driving wheel, the driven wheel is connected with the transmission support and is arranged at intervals along the first direction with the driving wheel, and the transmission belt is connected with the driving wheel and the driven wheel in a rolling way;

one end of the supporting piece is connected with the transmission belt, and the other end of the supporting piece is connected with the transmission bracket in a sliding mode along the first direction.

11. The film laminating apparatus as set forth in claim 1, further comprising:

12. A film sticking apparatus according to claim 1, wherein,

the film sticking device is also provided with a feeding position;

the supporting mechanism comprises a supporting piece and a rotating driving piece, wherein the supporting piece is used for bearing the product, and the rotating driving piece is connected with the supporting piece and used for driving the supporting piece to rotate between the feeding level and the film pasting position.