CN116394524A

CN116394524A - Optical lens film sticking method

Info

Publication number: CN116394524A
Application number: CN202310628156.3A
Authority: CN
Inventors: 林金润; 肖小林
Original assignee: Ningde Weitu Intelligent Technology Co ltd
Current assignee: Ningde Weitu Intelligent Technology Co ltd
Priority date: 2023-05-31
Filing date: 2023-05-31
Publication date: 2023-07-07

Abstract

The invention discloses an optical lens film pasting method, which applies an optical lens film pasting mechanism, wherein the optical lens film pasting mechanism comprises the following steps: a main body, a vacuum device and a heating assembly; a sealed film sticking cavity is formed in the main body, the film sticking cavity is sealed and divided into an upper cavity and a lower cavity by the film, and the lens is placed in the lower cavity; the heating component is used for heating the membrane in the membrane pasting cavity; the vacuum device is respectively and independently communicated with the upper chamber and the lower chamber so as to respectively and independently feed air or exhaust air to the upper chamber and the lower chamber; the method comprises the following steps: s1, respectively vacuumizing an upper chamber and a lower chamber through a vacuum device; s2, heating and softening the membrane through a heating assembly; s3, the upper cavity is subjected to air inlet and vacuum breaking through a vacuum device, so that the diaphragm is pushed by air pressure in the upper cavity to deform downwards and be adhered to the lens. The invention ensures that the quality and the efficiency of the optical lens film are higher.

Description

Optical lens film sticking method

Technical Field

The invention relates to the technical field of film sticking methods, in particular to an optical lens film sticking method.

Background

Part of the optical lenses need to be subjected to film pasting treatment, and the optical performance of the optical lenses is seriously affected by the quality of the film pasting.

The existing equipment for sticking films to planar or curved optical lenses is generally manufactured into profiling pressure heads or rollers which are matched with the surfaces of the optical lenses, films are placed on the optical lenses to be stuck with the films, then the pressure heads or rollers are used for pressing the films on the optical lenses, and then the films are stuck and stuck on the surfaces of the optical lenses.

Disclosure of Invention

The invention aims to provide a film pasting method for an optical lens, which overcomes the defects and ensures that the quality and the efficiency of the film pasting of the lens are higher.

To achieve the above object, the solution of the present invention is:

an optical lens film pasting method applies an optical lens film pasting mechanism, wherein the optical lens film pasting mechanism comprises a main body, a vacuum device and a heating component; a sealed film sticking cavity is formed in the main body, the film sticking cavity is sealed and divided into an upper cavity and a lower cavity by the film, and the lens is placed in the lower cavity; the heating component is used for heating the membrane in the membrane pasting cavity; the vacuum device is respectively and independently communicated with the upper chamber and the lower chamber, and the method comprises the following steps:

s1, respectively vacuumizing an upper chamber and a lower chamber through a vacuum device;

s2, heating and softening the membrane through a heating assembly;

s3, the upper cavity is subjected to air inlet and vacuum breaking through a vacuum device, so that the diaphragm is pushed by air pressure in the upper cavity to deform downwards and be adhered to the lens.

Further, the heating component of the optical lens film sticking mechanism is at least one of a laser heater, an infrared heater or a microwave heater, and in the step S2, the softening film is heated and separated by the heating component.

Further, in step S3, the upper chamber is filled with positive air pressure by a vacuum device.

Further, in step S3, the upper chamber is maintained for a predetermined period of time after the intake air is broken.

Further, the main body of the optical lens film sticking mechanism comprises an upper cavity component and a lower cavity component, the upper cavity component forms an upper cavity with an opening at the bottom, the lower cavity component forms a lower cavity with an opening at the top, a lens carrying table for carrying lenses is arranged in the lower cavity, and the upper cavity component is separated from or spliced with the upper cavity component, and the method comprises the following steps:

before the step S1, the upper cavity component and the lower cavity component are separated, a lens is placed on a lens carrier, a diaphragm is placed above the lens on the lens carrier, then the upper cavity component and the lower cavity component are spliced to form a film pasting cavity, and the diaphragm is clamped between the upper cavity component and the lower cavity component to seal and separate the upper cavity from the lower cavity.

Further, after step S3, the upper chamber assembly is separated from the lower chamber assembly, and the lens and the film attached to the lens are taken out together.

Further, in step S3, the upper chamber and the lower chamber are brought back to the atmospheric pressure before the upper chamber assembly is separated from the lower chamber assembly.

After the scheme is adopted, the gain effect of the invention is as follows: the diaphragm is between last cavity and lower cavity, with last cavity and lower cavity seal separation, and the lens is located down the cavity, and vacuum apparatus can be to last cavity and lower cavity evacuation respectively to avoid laminating the in-process at the lens with the diaphragm, lead to pressing from both sides air and impurity between diaphragm and the lens, soften the diaphragm through heating element heating, then make last cavity air inlet broken vacuum, can make the diaphragm down warp under the atmospheric pressure difference promotion between last cavity and lower cavity, paste on the lens of below.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic view of a partial perspective view of the upper chamber assembly and lower chamber assembly of the present invention;

FIG. 3 is a schematic view of a partial perspective view of the upper chamber assembly and the lower chamber assembly of the present invention;

FIG. 4 is a schematic perspective view of the lower chamber assembly and the linear motor of the lower chamber assembly of the present invention;

fig. 5 is a schematic perspective view of a vision collecting device for collecting the pose of a lens on a lens carrier;

FIG. 6 is a schematic diagram of a three-dimensional structure of a membrane feeding manipulator according to the present invention;

FIG. 7 is a schematic diagram of a three-dimensional structure of a membrane loading stage according to the present invention;

FIG. 8 is a schematic diagram of a perspective structure of a vision collection device for collecting the pose of a diaphragm on a diaphragm feeding manipulator according to the present invention;

FIG. 9 is a schematic view of the inside of the film cavity at step S2 of the present invention;

FIG. 10 is a schematic view of the present invention in the cavity of the film at step S3.

Description of the reference numerals:

1-diaphragm, 2-lens, 3-main body, 4-vacuum device, 5-heating component, 6-film pasting cavity, 7-upper cavity, 8-lower cavity, 9-upper cavity component, 10-lower cavity component, 11-lens carrier, 12-press driving mechanism, 13-upper cavity opening, 14-lower cavity opening, 15-transparent window, 16-diaphragm feeding manipulator, 17-vision acquisition equipment, 18-rack, 19-diaphragm feeding carrier, 20-plasma cleaning component, 21-upper cavity component portal frame, 22-lower cavity component linear motor, 23-alignment platform, 24-sucker, 25-manipulator displacement driving mechanism, 26-diaphragm feeding carrier linear motor.

Detailed Description

The invention will be described in detail with reference to the accompanying drawings and specific embodiments.

The optical lens film pasting mechanism applied by the invention, as shown in fig. 1-10, is used for pasting a film 1 on a lens 2, and is mainly shown in fig. 1 and 3, and comprises a frame 18, a main body 3, a pressing driving mechanism 12, a heating component 5, a film feeding manipulator 16 and a vision collecting device 17 which are arranged on the frame 18, and also comprises a vacuum device 4, wherein the arrangement position of the vacuum device 4 is not particularly limited, in the embodiment, the vacuum device is arranged beside the frame 18, and the parts arranged on the frame 18 can also not be arranged on the frame 18, and the arrangement position is not particularly limited;

as shown in fig. 3, 9 and 10, the main body 3 includes an upper cavity assembly 9 and a lower cavity assembly 10, an upper cavity 7 is formed in the upper cavity assembly 9, and an upper cavity opening 13 is formed at the bottom side of the upper cavity assembly 9, i.e. the upper cavity assembly 9 is in a groove shape with a downward opening; the lower cavity assembly 10 is positioned below the upper cavity assembly 9, a lower cavity 8 is formed in the lower cavity assembly 10, and a lower cavity opening 14 is formed in the top side of the lower cavity assembly 10, namely the lower cavity assembly 10 is in a groove shape with an upward opening;

the pressing driving mechanism 12 may be a pneumatic cylinder, an oil hydraulic cylinder or any other existing linear driving mechanism, the pressing driving mechanism 12 is connected to drive the upper cavity assembly 9 to lift, so that after the upper cavity assembly 9 and the lower cavity assembly 10 are assembled up and down to form the main body 3 after the upper cavity assembly 9 and the lower cavity assembly 10 are assembled up and down, the upper cavity opening 13 corresponds to the outline of the lower cavity opening 14, so that after the upper cavity assembly 9 and the lower cavity assembly 10 are assembled to form the main body 3, the upper cavity 7 and the lower cavity 8 form the film pasting cavity 6, a lens carrier 11 with a top surface for carrying the lens 2 and the diaphragm 1 is arranged in the lower cavity 8, the edge of the diaphragm 1 on the lens carrier 11 exceeds the range of the lower cavity opening 14 and the upper cavity opening 13, when the diaphragm 1 is placed on the lens carrier 11, the diaphragm 1 is clamped between the upper cavity assembly 9 and the lower cavity assembly 10 in a sealing manner, and the upper cavity 7 and the lower cavity 8 are separated in a sealing manner, so that a sealed cavity is formed; in a more specific embodiment, an upper cavity assembly gantry 21 is disposed on the frame 18, the upper cavity assembly 9 is disposed in the upper cavity assembly gantry 21, the pressing driving mechanism 12 is connected between the upper cavity assembly gantry 21 and the upper cavity assembly 9 to drive the upper cavity assembly 9 to lift on the gantry 21, the lower cavity assembly 10 is horizontally slidably disposed on the frame 18 through a lower cavity assembly linear motor 22, and a sliding path of the lower cavity assembly 10 passes through the upper cavity assembly gantry 21, so that the lower cavity assembly 10 can slide below the upper cavity assembly 9, in order to facilitate the placement of the lens 2 on the lens stage 11 for feeding, one end of the sliding path of the lower cavity assembly 10 is a side of the frame 18, in order to remove dust and impurities attached on the surface of the lens 2, a plasma cleaning assembly 20 facing the top surface of the lens stage 11 is further disposed, preferably, the plasma cleaning assembly 20 is disposed above the sliding path of the lower cavity assembly 10, so that when the lower cavity assembly 10 slides to the lower cavity assembly 10, the top surface of the lens stage 11 is blown toward the top surface of the lens stage 11, and the plasma cleaning assembly is carried by blowing gas toward the top surface of the lens stage 11;

the vacuum device 4 is a vacuum pump, and is respectively and independently communicated with the upper chamber 7 and the lower chamber 8, so that gas is respectively and independently fed into or pumped out from the upper chamber 7 and the lower chamber 8, and the vacuum device 4 can be any other existing device capable of pressurizing or depressurizing a closed cavity, and is not particularly limited;

the heating component 5 is used for heating the membrane 1 between the upper chamber 7 and the lower chamber 8, the heating component 5 can be any existing heating device, can be arranged in the upper chamber 7 and the lower chamber 8, can also be arranged outside the upper chamber 7 and the lower chamber 8, and preferably in the embodiment, in order to avoid the damage of the heating component 5 caused by the pressurization or depressurization in the upper chamber 7 and the lower chamber 8, the heating component 5 is arranged outside the upper chamber 7 and the lower chamber 8, is a space-free heating device capable of heating the membrane 1 in a space-free manner, and is more preferably at least one of a laser heater, an infrared heater or a microwave heater, a transparent window 15 is arranged on the upper chamber component 9 or the lower chamber component 10, and the heating component 5 is heated towards the membrane 1 through the transparent window 15.

In a preferred implementation, in combination with fig. 1 and 6, in order to align the optical axes of the membrane 1 and the lens 2 when the membrane 1 is placed on the lens carrier 11, the device further comprises a membrane feeding manipulator 16 and a vision collecting device 17 which are in communication with each other, the membrane feeding manipulator 16 is used for placing the membrane 1 on the lens carrier 11, the sliding path of the lower cavity assembly 10 further comprises a grabbing range of the membrane feeding manipulator 16, in combination with fig. 8, the vision collecting device 17 is used for collecting an image of the membrane 1 on the membrane feeding manipulator 16 to obtain a pose of the membrane 1 on the membrane feeding manipulator 16, in combination with fig. 5, and also collecting an image of the lens 2 on the lens carrier 11 to obtain a pose of the lens 2 on the lens carrier 11, in combination with fig. 6, the membrane feeding manipulator 16 is mounted on the frame 18 through a manipulator displacement driving mechanism 25, the manipulator displacement driving mechanism 25 may be any existing mechanism for driving the manipulator to displace, and is used for driving the manipulator 16 to translate and lift, the feeding manipulator 16 sucks the membrane 1 through the suction cup 24, the feeding manipulator 16 is provided with an alignment platform 23, the alignment platform 23 drives the suction cup 24 to move back and forth, left and right and rotate horizontally according to the pose of the membrane 1 on the membrane feeding manipulator 16 and the pose of the lens 2 on the lens carrier 11, so as to perform alignment adjustment, so that the optical axes on the membrane 1 and the lens 2 are aligned, preferably, in order to facilitate the feeding of the membrane 1, the frame 18 is further provided with a membrane feeding carrier 19 for carrying the membrane 1, the membrane feeding carrier 19 is slidingly arranged on the frame 18 under the driving of the membrane feeding carrier linear motor 26, and one end of the sliding path is the grabbing range of the membrane feeding manipulator 16, and the other end is the edge of the frame 18, so that the membrane 1 is fed from the edge of the frame 18.

The invention provides an optical lens film pasting method, which adopts an optical lens film pasting mechanism as described above, and comprises the following steps:

s1, firstly, the upper cavity component 9 is driven by the pressing driving mechanism 12 to be separated from the lower cavity component 10, the lower cavity component linear motor 22 drives the lower cavity component 10 to slide to the edge of the frame 18, the lens 2 is placed on the lens carrying platform 11, the diaphragm feeding carrying platform 19 slides to the edge of the frame 18, the diaphragm 1 is placed on the diaphragm feeding carrying platform 19, the diaphragm feeding carrying platform 19 slides to the grabbing range of the diaphragm feeding manipulator 16, the diaphragm feeding manipulator 16 sucks up the diaphragm 1, the lower cavity component linear motor 22 drives the lower cavity component 10 to slide to the grabbing range of the diaphragm feeding manipulator 16, the vision acquisition device 17 acquires images of the diaphragm 1 on the diaphragm feeding manipulator 16 and images of the lens 2 on the lens carrying platform 11 in the process, meanwhile, the plasma cleaning assembly 20 blows and cleans the surface of the lens 2 on the lens carrying table 11, the diaphragm feeding manipulator 16 performs position compensation, the diaphragm 1 is precisely placed above the lens 2 on the lens carrying table 11, the lower cavity assembly 10 is driven by the lower cavity assembly linear motor 22 to slide below the upper cavity assembly 9, the upper cavity assembly 9 and the lower cavity assembly 10 are driven by the pressing driving mechanism 12 to be combined, the upper cavity 7 and the lower cavity 8 are combined into the film pasting cavity 6, the diaphragm 1 is clamped between the upper cavity assembly 9 and the lower cavity assembly 10 so as to seal and separate the upper cavity 7 from the lower cavity 8, the upper cavity 7 and the lower cavity 8 are respectively vacuumized by the vacuum device 4 so as to remove air in the upper cavity 7 and the lower cavity 8, and air and impurities between the diaphragm 1 and the lens 2 are prevented from being mixed in the film pasting process;

s2, with emphasis on being combined with FIG. 9, the heating component 5 is used for heating and softening the membrane 1 at intervals;

s3, with emphasis on being combined with FIG. 10, the upper chamber 7 is subjected to air inlet and vacuum breaking through the vacuum device 4, so that the membrane 1 is pushed by air pressure in the upper chamber 7 to deform downwards and is adhered to the lens 2, positive air pressure is preferably introduced into the upper chamber 7 through the vacuum device 4, the upper chamber 7 is kept for a preset time after the air inlet and the vacuum breaking are carried out, then the upper chamber 7 and the lower chamber 8 are subjected to atmosphere pressure restoration, the upper chamber assembly 9 and the lower chamber assembly 10 are separated through the pressing driving mechanism 12, the lens 2 and the membrane 1 adhered to the lens 2 are taken out together, and the whole lens film adhering process is completed.

The above embodiments are only preferred embodiments of the present invention, and are not limited to the present invention, and all equivalent changes made according to the design key of the present invention fall within the protection scope of the present invention.

Claims

1. An optical lens film pasting method is characterized in that an optical lens film pasting mechanism is applied, and comprises a main body (3), a vacuum device (4) and a heating component (5); a sealed film pasting cavity (6) is formed in the main body (3), the film pasting cavity (6) is divided into an upper cavity (7) and a lower cavity (8) in a sealing mode by the film (1), and the lens (2) is placed in the lower cavity (8); the heating component (5) is used for heating the membrane (1) in the membrane pasting cavity (6); the vacuum device (4) is respectively and independently communicated with the upper chamber (7) and the lower chamber (8), and the method comprises the following steps:

s1, vacuumizing an upper chamber (7) and a lower chamber (8) through a vacuum device (4) respectively;

s2, heating and softening the membrane (1) through a heating component (5);

s3, air is introduced into the upper chamber (7) through the vacuum device (4) to break the vacuum, so that the membrane (1) is pushed by air pressure in the upper chamber (7) to deform downwards and be adhered to the lens (2).

2. The method for sticking optical lens according to claim 1, wherein: the heating component (5) of the optical lens film sticking mechanism is at least one of a laser heater, an infrared heater or a microwave heater, and in the step S2, the heating component (5) is used for heating and softening the film (1) at intervals.

3. A method for laminating an optical lens according to claim 1, wherein in step S3, positive air pressure is introduced into the upper chamber (7) through the vacuum device (4).

4. The method for sticking optical lens according to claim 1, wherein: in the step S3, the upper chamber (7) is kept for a preset time period after the vacuum is broken by air inlet.

5. A method of laminating an optical lens according to claim 1, wherein the main body (3) of the optical lens laminating mechanism to be applied includes an upper chamber assembly (9) and a lower chamber assembly (10), the upper chamber assembly (9) forming an upper chamber (7) with a bottom opening, the lower chamber assembly (10) forming a lower chamber (8) with a top opening, a lens stage (11) for carrying the lens (2) being provided in the lower chamber (8), the upper chamber assembly (9) being separated or spliced from the upper chamber assembly (9), the method comprising the steps of:

before the step S1, the upper cavity component (9) is separated from the lower cavity component (10), the lens (2) is placed on the lens carrying table (11), the diaphragm (1) is placed above the lens (2) on the lens carrying table (11), then the upper cavity component (9) is spliced with the lower cavity component (10), the upper cavity (7) and the lower cavity (8) are spliced into the film pasting cavity (6), and the diaphragm (1) is clamped between the upper cavity component (9) and the lower cavity component (10) so as to seal and separate the upper cavity (7) from the lower cavity (8).

6. The method for sticking optical lens according to claim 5, wherein: after step S3, the upper chamber assembly (9) is separated from the lower chamber assembly (10), and the lens (2) and the membrane (1) attached to the lens (2) are taken out together.

7. The method for sticking optical lens according to claim 6, wherein: in step S3, the upper chamber (7) and the lower chamber (8) are brought back to atmospheric pressure before the upper chamber assembly (9) is separated from the lower chamber assembly (10).