CN108859327B - 3D four-curved-surface glass film laminating device and method - Google Patents

Abstract

The invention discloses a 3D four-curved-surface glass film laminating device and a method, wherein the device comprises a film positioning part, a 3D glass positioning part and a laminating base which are sequentially connected from top to bottom, the film positioning part is used for carrying out profiling positioning and bonding on a film to be laminated, then the film positioning part is connected with the upper surface of the laminating base in a profiling way, the 3D glass positioning part is used for carrying out profiling positioning on the 3D glass to be laminated, after the film positioning part is removed, the protective films on the film and the surface of the 3D glass are uncovered, the 3D glass positioning part is connected with the upper surface of the laminating base in a profiling way, so that the film and the 3D glass are identical in azimuth and are not contacted, and then the film and the 3D glass are laminated under pressure. Through adopting the mode connection of profile modeling location, the laminating of being pressed under the vacuum condition, the simple structure of phenanthrene lin locating part, 3D glass locating part and laminating base in the whole device, convenient operation can effectively improve laminating efficiency and laminating quality, and is with low costs.

Description

3D four-curved-surface glass film laminating device and method

Technical Field

The invention relates to the technical field of 3D lamination, in particular to a 3D quadric-surface glass film lamination device and method.

Background

With the continuous development of technology, 3D products are becoming more and more abundant. Some 3D products require bonding with other components, such as 3D glass to film.

In the prior art, the 3D product is attached, and films are attached after being attached to the bearing film through expensive vacuum equipment for copying, CCD alignment and other processes, so that the problems of low efficiency, high cost, poor practicability and the like exist, the requirements of development and practicability cannot be met, and the large-scale popularization and application of the 3D product are not facilitated.

Disclosure of Invention

The invention aims to provide a 3D four-curved-surface glass film laminating device and method, which are simple in structure and convenient to operate, and can effectively solve the problems of low laminating efficiency, high cost, poor practicability and the like of the existing 3D glass film.

In order to solve the technical problems, the embodiment of the invention provides a 3D four-curved-surface glass film laminating device, which comprises a film positioning part, a 3D glass positioning part and a laminating base which are sequentially connected from top to bottom, wherein the film positioning part is used for carrying out profiling positioning and bonding on a film to be laminated and then is connected with the upper surface of the laminating base in a profiling manner, the 3D glass positioning part is used for carrying out profiling positioning on the 3D glass to be laminated, the film positioning part is used for removing the film positioning part, the protective film on the surface of the 3D glass is uncovered, and the 3D glass positioning part is connected with the upper surface of the laminating base in a profiling manner, so that the film and the 3D glass are identical in azimuth and are not contacted, and then are laminated under pressure.

The laminating base comprises a main fixing plate and a profiling silica gel block, wherein a gel block positioning groove used for placing the profiling silica gel block is formed in the upper surface of the main fixing plate, the profiling silica gel block is clamped with the gel block positioning groove through a bottom clamping buckle, and the film is adhered with the profiling silica gel block in a profiling mode.

The laminating base is further provided with a film positioning pin hole and a glass positioning pin hole through the supporting pin, the film positioning pin hole, the glass positioning pin hole, the film positioning component and the 3D glass positioning component.

The support pin is a lifting support pin provided with a spring mechanism.

The film positioning component comprises a film profiling positioning structure, a film silicon rubber strip groove arranged in the film profiling positioning structure and a film adhesive silicon rubber strip arranged in the film silicon rubber strip groove, and the film is adhered to the film adhesive silicon rubber strip after being profiled and positioned by the film profiling positioning structure.

The 3D glass positioning component comprises a 3D glass profiling positioning structure, a 3D glass silica gel strip groove arranged in the 3D glass profiling positioning structure and a 3D glass adhesive silica gel strip arranged in the 3D glass silica gel strip groove, and the 3D glass is adhered to the 3D glass adhesive silica gel strip after being profiled and positioned by the 3D glass profiling positioning structure.

In addition, the embodiment of the invention also provides a 3D quadric surface glass film laminating method, which comprises the following steps:

step 1, positioning a film through a film profiling positioning structure arranged on a film positioning component;

step 2, positioning the 3D glass by using a glass profiling positioning structure arranged on the 3D glass positioning component;

step 3, connecting the film positioning component with a bonding base, and taking down the film positioning component after the film is bonded with a profiling silica gel block arranged on the bonding base in a profiling way;

step 4, removing the protective film arranged on the surfaces of the film and the 3D glass;

step 5, connecting the 3D glass positioning component with the attaching base so that the film and the 3D glass are in the same direction and are not contacted;

and 6, placing the attaching base provided with the film and the 3D glass in a vacuum environment, so that the film and the 3D glass are attached under pressure.

Wherein, will 3D glass positioning part with laminating base is connected for will 3D glass positioning part with laminating base round pin is connected.

Wherein, the step 6 includes: and placing the attaching base provided with the film and the 3D glass in a vacuum environment with a vacuum value lower than 50pa, so that the film is attached to the 3D glass.

Wherein, the step 6 further comprises: the film and the 3D glass are bonded under a force of 6kgf or more applied to the 3D glass positioning member.

Compared with the prior art, the device and the method for attaching the 3D quadric-surface glass film provided by the embodiment of the invention have the following advantages:

the embodiment of the invention provides a 3D four-curved-surface glass film laminating device which comprises a film positioning part, a 3D glass positioning part and a laminating base, wherein the film positioning part, the 3D glass positioning part and the laminating base are sequentially connected from top to bottom, the film positioning part is used for carrying out profiling positioning and bonding on films to be laminated and then is connected with the upper surface of the laminating base in a profiling manner, the 3D glass positioning part is used for carrying out profiling positioning on the 3D glass to be laminated, the protective films on the surfaces of the film and the 3D glass are uncovered after the film positioning part is removed, and the 3D glass positioning part is connected with the upper surface of the laminating base in a profiling manner, so that the directions of the film and the 3D glass are identical and are not contacted, and then the film and the 3D glass are laminated under pressure.

The 3D quadric surface glass film laminating method provided by the embodiment of the invention comprises the following steps:

step 1, positioning a film through a film profiling positioning structure arranged on a film positioning component;

step 2, positioning the 3D glass by using a glass profiling positioning structure arranged on the 3D glass positioning component;

step 3, connecting the film positioning component with a bonding base, and taking down the film positioning component after the film is bonded with a profiling silica gel block arranged on the bonding base in a profiling way;

step 4, removing the protective film arranged on the surfaces of the film and the 3D glass;

step 5, connecting the 3D glass positioning component with the attaching base so that the film and the 3D glass are in the same direction and are not contacted;

and 6, placing the attaching base provided with the film and the 3D glass in a vacuum environment, so that the film and the 3D glass are attached under pressure.

According to the 3D four-curved-surface glass film laminating device and method, a film is arranged on a film positioning component in a profiling positioning mode, 3D glass is arranged on a 3D glass positioning component, then the film positioning component is connected with a laminating base, after the film is adhered to the profiling of the laminating base, the film positioning component is taken down, a protective film arranged on the surfaces of the film and the 3D glass is removed, the 3D glass positioning component is connected with the laminating base, so that the film and the 3D glass are identical in azimuth and are not contacted, and finally the laminating base provided with the film and the 3D glass is placed in a vacuum environment, so that the film and the 3D glass are laminated under pressure in a vacuum condition.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is an exploded schematic view of a specific implementation of a 3D quadric glass film laminating device according to an embodiment of the present invention;

fig. 2 is a schematic step flow diagram of a specific implementation of a 3D quadric glass film laminating method according to an embodiment of the present invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1 to fig. 2, fig. 1 is an exploded structural schematic diagram of a specific implementation manner of a 3D quadric-surface glass film laminating device according to an embodiment of the present invention; fig. 2 is a schematic step flow diagram of a specific implementation of a 3D quadric glass film laminating method according to an embodiment of the present invention.

In a specific embodiment, the 3D four-curved-surface glass film laminating device comprises a film positioning component 10, a 3D glass positioning component 20 and a laminating base 50 which are sequentially connected from top to bottom, wherein the film positioning component 10 is used for carrying out profiling positioning and bonding on a film 40 to be laminated and then is connected with the upper surface of the laminating base 50, the 3D glass positioning component 20 is used for carrying out profiling positioning on a 3D glass 30 to be laminated, after the film positioning component 10 is removed, the protective film on the surface of the film 40 and the surface of the 3D glass 30 is uncovered, the 3D glass positioning component 20 is connected with the upper surface of the laminating base 50 in a profiling manner, so that the film 40 and the 3D glass 30 are identical in orientation and are not contacted, and then are laminated under pressure.

Through adopting the mode of profile modeling location to set up film 40 at film locating part 10, with 3D glass 30 sets up at 3D glass locating part 20, then be connected film locating part 10 with laminating base 50, after film 40 and the profile modeling bonding at laminating base 50, take off film locating part 10, take off the protection film that sets up at film 40, 3D glass 30 surface again, will 3D glass locating part 20 with laminating base 50 is connected for film 40 with 3D glass 30 position is the same and contactless, will be provided with film 40 with laminating base 50 of 3D glass 30 is arranged in the vacuum environment at last, makes film 40 with 3D glass 30 is laminated under the vacuum condition, film locating part 10, 3D glass locating part 20 and laminating base 50 simple structure in the whole device, laminating process convenient operation can effectively improve laminating efficiency and laminating quality, and with low costs.

In the present invention, in the process of connecting the lamination base 50 with the 3D glass positioning component 20 and the film positioning component 10, the 3D glass positioning component 20 and the film positioning component 10 need to ensure the positioned 3D glass 30 and the film 40 to be laminated in the vacuum environment in the later stage, so that the relative position of the 3D glass 30 on the 3D glass positioning component 20 and the relative position of the film 40 on the film positioning component 10 are generally the same, even the connection means and the connection position of the 3D glass positioning component 20 and the film positioning component 10 can be the same as those of the lamination base 50, the position difference of the two in the lamination process is reduced, and the lamination quality and the lamination efficiency are improved.

In order to further improve the bonding quality, in an embodiment of the present invention, the bonding base 50 includes a main fixing plate 52 and a profiling silica gel block 51, a gel block positioning groove for placing the profiling silica gel block 51 is provided on the upper surface of the main fixing plate 52, the profiling silica gel block 51 is clamped with the gel block positioning groove by a buckle provided at the bottom, and the film 40 is adhered to the profiling silica gel block 51 in a profiling manner.

The silica gel piece constant head tank is designed with the structure of profile modeling silica gel piece 51, profile modeling silica gel piece 51 below buckle design and constant head tank cooperation, guarantees that the silica gel piece is fixed firm not hard up.

It should be noted that the size of the glue block positioning groove and the specific position of the main fixing plate 52 are not specifically limited in the present invention, and the hardness and viscosity of the contoured glue block 51 are not specifically limited.

It should be noted that in the present invention, the profiling refers to the same pattern as the corresponding pattern, for example, the profiling silica gel block 51 refers to the pattern whose upper surface is exactly the same as the projection of the film 40, 3D curved glass in the horizontal plane.

In order to further improve the laminating efficiency and reduce the complexity of operation, the laminating base 50 further comprises a supporting pin arranged on the upper surface of the main fixing plate 52, the main fixing plate 52 is provided with a film 40 positioning pin hole and a glass positioning pin hole, and the laminating base 50 is in pin joint with the film positioning component 10 and the 3D glass positioning component 20 through the supporting pin, the film 40 positioning pin hole, the glass positioning pin hole and the glass positioning pin hole.

Through adopting the mode of pin joint to connect at laminating in-process, can be quick with laminating base 50 with film locating part 10 3D glass locating part 20 is connected, and the operation is simple promptly, and the accuracy is extremely high moreover, and the repeatability is good, can not take place the problem of alignment error.

It should be noted that in the present invention, in addition to the use of the pin joint, the bolt connection may be used, but the use of the bolt connection requires the installation and disassembly of the bolt, which increases the complexity of the operation, increases the time for fitting use, and decreases the efficiency of the carrying case, and it should be noted that the positions and the number of the pin-jointed pin posts and pin-jointed holes are not limited, and in order to avoid the extra operation complexity caused by symmetry, the pin-jointed posts and pin-jointed holes are generally not symmetrically arranged on the main fixing plate 52, and in addition, the same pin holes may be used for the pin joint with the film positioning member 10 and the 3D glass positioning member 20, or different pin holes may be used, and in order to avoid or reduce the contact between the film 40 and the 3D glass 30 before vacuum fitting in the two connection processes, different pin holes are used.

Still further, in order to avoid or reduce contact of the film 40 with the 3D glass 30 prior to vacuum lamination during the two connection, different pin holes are used, the support pins being floatable support pins provided with spring mechanisms. The contact between the film 40 and the 3D glass 30 can be reduced in the process of connecting the 3D glass positioning component 20 and the bonding base 50 through the supporting pins, so that no air bubbles exist between the film 40 and the 3D glass 30 after bonding, and bonding quality is improved.

Because the film positioning component 10 is to connect the film 40 to be laminated with the upper surface of the lamination base 50 after being subjected to profiling positioning and bonding, the specific connection mode of the film 40 and the film positioning component 10 is not limited in the invention, in one embodiment, the film positioning component 10 comprises a film 40 profiling positioning structure, a film 40 silica gel strip groove arranged in the film 40 profiling positioning structure and a film 40 adhesive silica gel strip arranged in the film 40 silica gel strip groove, and the film 40 is subjected to profiling positioning by the film 40 profiling positioning structure and then bonded with the film 40 adhesive silica gel strip.

Film 40 is arranged in the film 40 profiling positioning structure to perform profiling positioning, and film 40 adhesive silica gel strips of the film 40 silica gel strip grooves arranged in the film 40 profiling positioning structure are adhered, so that the connection speed and the connection efficiency can be improved, and the laminating efficiency of the whole laminating process can be improved.

Similarly, in order to further improve the efficiency of the 3D glass positioning member 20 in connecting the 3D glass 30 in a profiling manner, in one embodiment of the present invention, the 3D glass positioning member 20 includes a 3D glass 30 profiling positioning structure, a 3D glass 30 silica gel strip groove provided in the 3D glass 30 profiling positioning structure, and a 3D glass 30 adhesive silica gel strip provided in the 3D glass 30 silica gel strip groove, and the 3D glass 30 is adhered to the 3D glass 30 adhesive silica gel strip after being profiled and positioned by the 3D glass 30 profiling positioning structure.

It should be noted that the shape and size of the adhesive silica gel strip of the 3D glass 30 and the adhesive silica gel strip of the film 40 are not specifically limited, but in order to reduce the complexity of the process, the dimensions of the adhesive silica gel strip of the film 40 and the adhesive silica gel strip of the glass are identical, and the materials are identical, and the hardness of the adhesive silica gel strip of the film 40 and the adhesive silica gel strip of the glass is 15 ° to 16 °, in one embodiment, the hardness of the adhesive silica gel strip of the film 40 and the adhesive silica gel strip of the glass is 15 °.

The laminating base 50 is further provided with a lower sealing plate 53 arranged at the bottom of the main fixing plate 52, and is used for ensuring the integrity and surface level of the main fixing plate 52, so that relative sliding cannot occur in the process of pressure lamination in a vacuum environment, and laminating quality is improved.

In one embodiment of the invention, the application method of the 3D quadric surface glass film lamination comprises the following steps:

firstly, positioning a film on a film positioning component in a profiling positioning structure, pressing to adhere the film to an adhesive silica gel strip, pressing down a positioning pin of the film positioning component in a matched manner with a film positioning pin hole of a bonding base, profiling the film and adhering the profiling silica gel block due to the fact that the profiling silica gel block is profiling and has adhesive property, and taking down the film positioning component after finishing;

then positioning the 3D glass on a 3D glass positioning component in a profiling positioning structure, pressing to adhere the glass to the adhesive silica gel strips, then uncovering the protective films on the surfaces of the films and the 3D glass, matching the positioning pin holes of the glass positioning component with the glass positioning pins attached to the base, and enabling the 3D glass to be not contacted with the film at intervals under the action of the supporting pins by the glass positioning component;

finally, the jig is placed in a cavity of vacuum equipment to be vacuumized, when the vacuum value is lower than 50pa, the equipment plane is pressed down to enable the 3D glass to be attached to the film (the pressure is 6 kgf) in a vacuum environment, after the attaching time is reached, the equipment taking-out device is opened, the glass positioning part is taken down by using the taking-out hand position, the product is taken out, and the device has good practicability due to simple operation and high efficiency in the process.

In addition, the embodiment of the invention also provides a 3D quadric surface glass film laminating method, which comprises the following steps:

step 1, positioning a film through a film profiling positioning structure arranged on a film positioning component; in the process, the film is required to be connected in an adhesive mode because the film cannot move relative to the film positioning component before the film positioning component is connected with the attaching base.

Step 2, positioning the 3D glass by using a glass profiling positioning structure arranged on the 3D glass positioning component;

step 3, connecting the film positioning component with a bonding base, and taking down the film positioning component after the film is bonded with a profiling silica gel block arranged on the bonding base in a profiling way;

step 4, removing the protective film arranged on the surfaces of the film and the 3D glass;

step 5, connecting the 3D glass positioning component with the attaching base so that the film and the 3D glass are in the same direction and are not contacted;

and 6, placing the attaching base provided with the film and the 3D glass in a vacuum environment, so that the film and the 3D glass are attached under pressure.

In order to improve the laminating connection efficiency, the 3D glass positioning component and the laminating base are connected to be in pin connection with the 3D glass positioning component and the laminating base. Therefore, the pin joint is only needed to be carried out, the alignment can be automatically carried out without carrying out position determination, the process complexity is reduced, and the laminating efficiency is improved, and the invention is not limited to the specific position and structure of the pin joint, but the laminating base is required to be connected with the 3D glass positioning component and the film positioning component in sequence, so that the pin post is arranged on the laminating base, and the pin holes are arranged on the other components, and the invention is not limited to the specific position and structure of the pin joint. Of course, the pin joint may be changed to a bolt joint in the present invention to obtain a similar effect, which is not particularly limited in the present invention.

While the present invention is not limited to this, and in one embodiment, the step 6 includes: and placing the attaching base provided with the film and the 3D glass in a vacuum environment with a vacuum value lower than 50pa, so that the film is attached to the 3D glass. The vacuum is used in a manner that minimizes or eliminates air bubbles that may be generated between the film and the 3D glass.

The present invention does not specifically limit the force applied in the fitting, and the step 6 further includes: the film and the 3D glass are bonded under a force of 6kgf or more applied to the 3D glass positioning member.

In one embodiment, the film and the 3D glass are bonded under a force of 6kgf applied to the 3D glass positioning member.

In summary, according to the 3D four-curved-surface glass film laminating device and method provided by the embodiment of the invention, the film is arranged on the film positioning component in a profiling positioning manner, the 3D glass is arranged on the 3D glass positioning component, then the film positioning component is connected with the laminating base, after the film is adhered to the profiling of the laminating base, the film positioning component is taken down, the protective film arranged on the surfaces of the film and the 3D glass is removed, the 3D glass positioning component is connected with the laminating base, so that the film and the 3D glass are identical in orientation and not in contact, and finally the laminating base provided with the film and the 3D glass is placed in a vacuum environment, so that the film and the 3D glass are laminated under the vacuum condition.

The device for the 3D quadric-surface glass film laminating device and the device for the method provided by the invention are described in detail. The principles and embodiments of the present invention have been described herein with reference to specific examples, the description of which is intended only to facilitate an understanding of the method of the present invention and its core ideas. It should be noted that it will be apparent to those skilled in the art that various modifications and adaptations of the invention can be made without departing from the principles of the invention and these modifications and adaptations are intended to be within the scope of the invention as defined in the following claims.

Claims (8)

1. The utility model provides a 3D four curved surface glass film laminating device, its characterized in that, includes film locating part, 3D glass locating part and the laminating base that from the top down connects gradually that set up, film locating part will need laminate the film behind the profile modeling location bonding with the upper surface profile modeling connection of laminating base, 3D glass locating part will need laminate the 3D glass profile modeling location, will after getting rid of film locating part will the film the protection film on 3D glass surface is uncovered, will 3D glass locating part with the upper surface profile modeling connection of laminating base for the film with 3D glass position is the same and contactless, then receives the laminating under vacuum condition, the laminating base includes main fixed plate and profile modeling silica gel piece, the upper surface of main fixed plate is provided with the rubber piece constant head tank that is used for placing the profile modeling silica gel piece, profile modeling silica gel piece through setting up in the bottom buckle with the rubber piece constant head tank joint, film with the film is glued with the silica gel piece, film is in the film setting up through the adhesive structure of film locating part film in the adhesive tape setting up the adhesive tape of film location.

2. The 3D quadric surface glass film laminating device of claim 1, wherein the laminating base further comprises a supporting pin arranged on the upper surface of the main fixing plate, the main fixing plate is provided with a film positioning pin hole and a glass positioning pin hole, and the laminating base is in pin joint with the film positioning component and the 3D glass positioning component through the supporting pin, the film positioning pin hole and the glass positioning pin hole.

3. The 3D quadric glass film laminating device of claim 2, wherein the support pins are liftable support pins provided with spring mechanisms.

4. The 3D four-curved-surface glass film laminating device according to claim 1, wherein the 3D glass positioning component comprises a 3D glass profiling positioning structure, a 3D glass silica gel strip groove arranged in the 3D glass profiling positioning structure and a 3D glass adhesive silica gel strip arranged in the 3D glass silica gel strip groove, and the 3D glass is adhered to the 3D glass adhesive silica gel strip after being profiled and positioned by the 3D glass profiling positioning structure.

5. The 3D quadric surface glass film laminating method is characterized by comprising the following steps of:

step 1, positioning a film through a film profiling positioning structure arranged on a film positioning component;

step 2, positioning the 3D glass by using a glass profiling positioning structure arranged on the 3D glass positioning component;

step 3, connecting the film positioning component with a bonding base, and taking down the film positioning component after the film is bonded with a profiling silica gel block arranged on the bonding base in a profiling way;

step 4, removing the protective film arranged on the surfaces of the film and the 3D glass;

step 5, connecting the 3D glass positioning component with the attaching base so that the film and the 3D glass are in the same direction and are not contacted;

step 6, placing the attaching base provided with the film and the 3D glass in a vacuum environment, so that the film and the 3D glass are attached under pressure;

the laminating base comprises a main fixing plate and a profiling silica gel block, wherein a gel block locating groove for placing the profiling silica gel block is formed in the upper surface of the main fixing plate, the profiling silica gel block is clamped with the gel block locating groove through a bottom clamp, a film is adhered to the profiling silica gel block in a profiling mode, the film locating part comprises a film profiling locating structure, a film silica gel groove arranged in the film profiling locating structure and a film adhesive silica gel strip arranged in the film silica gel groove, and the film is adhered to the film adhesive silica gel strip after being profiled and located by the film profiling locating structure.

6. The method of attaching a 3D quadric glass film according to claim 5, wherein the connecting the 3D glass positioning member with the attaching base is a pinning the 3D glass positioning member with the attaching base, wherein the attaching base is provided with a pin, and the 3D glass positioning member is provided with a pin hole.

7. The method for attaching a 3D quadric glass film as defined in claim 5, wherein said step 6 comprises: and placing the attaching base provided with the film and the 3D glass in a vacuum environment with a vacuum value lower than 50pa, so that the film is attached to the 3D glass.

8. The method for attaching a 3D quadric glass film as defined in claim 7, wherein said step 6 further comprises: the film and the 3D glass are bonded under a force of 6kgf or more applied to the 3D glass positioning member.