CN113909063B

CN113909063B - Coating device for optical lens processing

Info

Publication number: CN113909063B
Application number: CN202111106149.4A
Authority: CN
Inventors: 徐雁
Original assignee: Shangrao Tongyu Photoelectric Technology Co ltd
Current assignee: Shangrao Tongyu Photoelectric Technology Co ltd
Priority date: 2021-09-22
Filing date: 2021-09-22
Publication date: 2022-09-02
Anticipated expiration: 2041-09-22
Also published as: CN113909063A

Abstract

The invention relates to a coating device, in particular to a coating device for processing an optical lens. The invention aims to provide a coating device for processing an optical lens, which can uniformly heat the lens and can coat a film in a high-vacuum chamber. In order to solve the technical problem, the invention provides a coating device for processing an optical lens, which comprises a first bracket, a box body, a sliding door, a handle, a limiting block, a first guide rail, a first sliding block, a placing disc, a first support plate, an electron gun, a refractor, a second support plate and the like; the left and right sides of the lower part of the box body are connected with first supports, the front side of the box body is connected with a sliding door in a sliding mode, and the right end of the front side of the sliding door is connected with a handle. The invention can heat the optical lens through the electron gun and the refractor, improve the film coating effect, and can pull the placing disc out of the box body through the movement of the first slide block on the first guide rail.

Description

Coating device for optical lens processing

Technical Field

The invention relates to a coating device, in particular to a coating device for processing an optical lens.

Background

The coating is to attach hundreds of nanometers of thin layers of other materials on the surface of the lens. The coating on the surface of the lens is usually physical evaporation in a vacuum chamber, that is, a process of heating the coating material to an evaporation temperature in a vacuum environment to deposit the coating on the lens substrate.

Through searching, the patent application numbers are: CN201821378543.7 discloses an optical lens coating device, including a coating film section of thick bamboo, the bottom fixedly connected with of coating film section of thick bamboo is used for the heating mechanism of optical lens coating film, fixedly connected with actuating mechanism on the lateral wall of coating film section of thick bamboo, actuating mechanism's drive end runs through the lateral wall of coating film section of thick bamboo and extends to inside it, actuating mechanism is located the one end fixedly connected with slewing mechanism in the coating film section of thick bamboo, the last clamping mechanism that is equipped with of slewing mechanism, the opening part of coating film section of thick bamboo is equipped with assorted cover with it, cover and coating film section of thick bamboo sealing connection.

The above patent has the defects that the lens is difficult to be uniformly heated, and the coating can not be finished in a vacuum chamber, so that the coating effect is poor.

Therefore, it is necessary to design a coating apparatus for processing an optical lens, which can uniformly heat a lens and can perform coating in a high vacuum chamber.

Disclosure of Invention

(1) Technical problem to be solved

In order to overcome the defects that the lens is difficult to uniformly heat and the coating in a vacuum chamber cannot be completed, so that the coating effect is poor, the invention provides the coating device for processing the optical lens, which can uniformly heat the lens and can perform coating in a high-vacuum chamber.

(2) Technical scheme

In order to solve the technical problems, the invention provides a coating device for processing optical lenses, which comprises a first bracket, a box body, a sliding door, a handle, a limiting block, a first guide rail, a first slide block, a placing disc, a first support plate, an electron gun, a refractor, a second support plate, a motor, a first rubber wheel and a second rubber wheel, wherein the first bracket is connected with the left side and the right side of the lower part of the box body, the sliding door is connected with the front side of the box body in a sliding manner, the handle is connected with the right end of the front side of the sliding door, the limiting block is connected with the right part of the front side of the sliding door, the first guide rail is connected with the bottom in the box body, the first slide block is connected with the first guide rail in a sliding manner, the placing disc is connected with the first slide block in a rotating manner, four placing grooves are uniformly arranged on the top of the placing disc in the circumferential direction at intervals, the first support plate is connected with the left side of the box body, the electron gun is installed on the first support plate, the refractor for receiving a light source of the electron gun is connected with the top of the box body on the right side, the lower portion of the inner right side wall of the box body is connected with a second supporting plate, the motor is installed at the left end of the second supporting plate, the output shaft of the motor is connected with a first rubber wheel, the bottom of the placing disc is connected with a second rubber wheel, and the second rubber wheel is in contact fit with the first rubber wheel.

Preferably, the clamping mechanism comprises a second guide rail, a second sliding block, a first spring, an oblique block and a second spring, the bottom of the inner side of the box body is connected with the two second guide rails, the two second guide rails are bilaterally symmetrical, the second guide rail is connected with the second sliding block in a sliding mode, the first spring is connected between the second sliding block and the second guide rail, the oblique block used for blocking the first sliding block is connected to the middle of the second sliding block in a sliding mode, and the second spring is connected between the oblique block and the second sliding block.

Preferably, the material pushing device is further included and comprises a second support, a rodless cylinder, a connecting block, a material pushing block and an inclined rod, the second support is connected to the left side of the inner bottom of the box body, the rodless cylinder is mounted on the second support, the connecting block is connected to the rodless cylinder, the material pushing block is connected to the right side of the connecting block, the inclined rods are connected to the left side and the right side of the rear portion of the material pushing block, and the inclined rods are in contact with the second sliding block.

Preferably, the air exhaust mechanism comprises a third support plate, an air pump, an air exhaust pipe and an exhaust pipe, the lower portion of the right side of the box body is connected with the third support plate, the air pump is mounted on the third support plate, the air inlet end of the air pump is connected with the air exhaust pipe, the air exhaust pipe penetrates through the right wall of the box body, and the air outlet end of the air pump is connected with the exhaust pipe.

Preferably, the blanking mechanism comprises a fourth supporting plate, a blanking frame and a blanking pipe, the fourth supporting plate is connected to the upper portion of the rear side of the box body, the blanking frame is connected to the top of the fourth supporting plate, the lower portion of the blanking frame penetrates through the rear side wall of the box body, four blanking pipes are connected to the bottom of the blanking frame, and the blanking pipes are located above the eccentric position of the placement disc.

Preferably, still including quantitative mechanism, quantitative mechanism is including the arc rack, the mounting bracket, the material blocking piece, the gear, third support and torsion spring, the circumferencial direction of placing the dish is connected with four arc racks evenly at the interval, back wall middle part is connected with the mounting bracket in the box, open the front end of mounting bracket has four relief holes, the lower extreme and the mounting bracket top contact of unloading pipe, the relief hole is located the unloading pipe under, the front side bottom rotary type of mounting bracket is connected with the gear, arc rack and gear engagement, the hollow setting in gear middle part, the hollow department of gear is connected with the material blocking piece that is cross, the material blocking piece is used for plugging up the relief hole, the front end upper portion of mounting bracket is connected with the third support, be connected with torsion spring between third support and the material blocking piece.

Preferably, the sliding door further comprises a sealing mechanism, the sealing mechanism comprises a rubber strip and a magnet, the right side of the sliding door is connected with the rubber strip, and the front side of the left end face of the box body is connected with the magnet in an embedded mode.

Preferably, a limiting plate is arranged at the left end of the sliding door, and the limiting plate is made of iron.

(3) Advantageous effects

1. The electronic gun and the refractor can heat the optical lens, so that the film coating effect is improved, and the placing disc can be pulled out of the box body by moving the first sliding block on the first guide rail, so that people can conveniently take and place the optical lens.

2. The clamping mechanism can be used for positioning the first sliding block, and when the optical lens is coated, the first sliding block can be prevented from moving on the first guide rail at will, so that the stability of coating is ensured.

3. The arranged air exhaust mechanism can exhaust the box body into a high-vacuum coating cavity, so that the optical lens is coated in the vacuum cavity, and the coating effect can be improved.

4. The automatic coating liquid adding can be realized through the matching of the blanking mechanism and the quantifying mechanism, the coating liquid is not required to be manually coated on the optical lens, and the automatic coating device has the characteristics of low labor intensity and high working efficiency.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a partial perspective view of the present invention.

Fig. 3 is a first partial cross-sectional view of the present invention.

Fig. 4 is a second partial cross-sectional view of the present invention.

Fig. 5 is a schematic perspective view of the chucking mechanism of the present invention.

Fig. 6 is an enlarged view of part a of the present invention.

Fig. 7 is a first partial cross-sectional view of the pusher mechanism of the present invention.

Figure 8 is a second partial cross-sectional view of the pusher mechanism of the present invention.

FIG. 9 is a perspective view of the air pumping mechanism of the present invention.

Fig. 10 is a schematic perspective view of the blanking mechanism of the present invention.

Fig. 11 is a partial cross-sectional view of the blanking mechanism of the present invention.

Figure 12 is a partial cross-sectional view of the dosing mechanism of the present invention.

Fig. 13 is a schematic view of a first partially-separated body structure of the dosing mechanism of the present invention.

FIG. 14 is a view showing a state of use of the quantitative mechanism of the present invention.

Fig. 15 is a schematic view of a second partial body structure of the dosing mechanism of the present invention.

FIG. 16 is a first state of use of the closure mechanism of the present invention.

FIG. 17 is a second state of use of the closure mechanism of the present invention.

The labels in the figures are: 1-a first bracket, 2-a box body, 3-a sliding door, 4-a handle, 5-a limiting block, 6-a first guide rail, 7-a first slide block, 8-a placing disc, 9-a first support plate, 10-an electron gun, 11-a refractor, 12-a second support plate, 13-a motor, 14-a first rubber wheel, 15-a second rubber wheel, 16-a clamping mechanism, 161-a second guide rail, 162-a second slide block, 163-a first spring, 164-an oblique block, 165-a second spring, 17-a pushing mechanism, 171-a second bracket, 172-a rodless cylinder, 173-a connecting block, 174-a pushing block, 175-an oblique rod, 18-an air exhaust mechanism, 181-a third support plate, 182-an air pump, 183-an air exhaust pipe, 184-exhaust pipe, 19-blanking mechanism, 191-fourth support plate, 192-blanking frame, 193-blanking pipe, 20-quantitative mechanism, 201-arc rack, 202-mounting rack, 203-blocking block, 204-gear, 205-third support, 206-torsion spring, 21-sealing mechanism, 211-rubber strip, 212-magnet.

Detailed Description

The invention is further described below with reference to the figures and examples.

Example 1

A coating device for processing optical lenses is shown in figures 1-4 and comprises a first bracket 1, a box body 2, a sliding door 3, a handle 4, a limiting block 5, a first guide rail 6, a first slide block 7, a placing disc 8, a first support plate 9, an electron gun 10, a refractor 11, a second support plate 12, a motor 13, a first rubber wheel 14 and a second rubber wheel 15, wherein the left side and the right side of the lower part of the box body 2 are connected with the first bracket 1 in a welding connection mode, the front side of the box body 2 is movably connected with the sliding door 3, the left side of the box body 2 is provided with a strip-shaped through hole, the sliding door 3 penetrates through the strip-shaped through hole, the left end of the sliding door 3 is provided with a limiting plate made of iron, the right end of the front side of the sliding door 3 is connected with the handle 4 in a welding connection mode, the right end of the front side of the sliding door 3 is connected with the limiting block 5 in a bolt connection mode, the inner bottom of the box body 2 is connected with the first guide rail 6, first guide rail 6 is the level setting, be connected with first slider 7 on first guide rail 6 with sliding type, be connected with through axostylus axostyle rotary type on first slider 7 and place dish 8, it has four standing grooves to place even interval ground of dish 8 top circumference, the shape of standing groove is circular, the left side of box 2 is connected with first extension board 9, first extension board 9 is the slope setting, install electron gun 10 on the first extension board 9, the top right side of box 2 is connected with refractor 11 of receiving electron gun 10 light source, the mode that bolted connection was passed through to the interior right side wall lower part of box 2 is connected with second extension board 12, motor 13 is installed to the left end of second extension board 12, be connected with first rubber wheel 14 on motor 13's the output shaft, the bottom of placing dish 8 is connected with second rubber wheel 15, all be equipped with anti-skidding line on second rubber wheel 15 and the first rubber wheel 14, second rubber wheel 15 and the cooperation of first rubber wheel 14 contact.

Pulling the handle 4 leftwards to open the sliding door 3, limiting the sliding door 3 by the limiting block 5 to prevent the sliding door 3 from separating from the box body 2, pulling the first sliding block 7 to move forwards to the foremost end of the first guide rail 6, placing the optical lens in the placing groove of the placing disc 8, then pushing the first sliding block 7 to reset backwards, then resetting the placing disc 8 backwards to move back into the box body 2, coating the coating liquid on the optical lens, closing the sliding door 3, then starting the electronic gun 10 to emit strong light, receiving the strong light emitted by the electronic gun 10 by the refractor 11 and projecting the strong light onto the optical lens, so that the coating liquid can be solidified and attached on the optical lens, then starting the motor 13 to rotate to drive the first rubber wheel 14 to rotate for a circle, driving the second rubber wheel 15 to rotate for 90 degrees through the first rubber wheel 14, driving the placing disc 8 to rotate for 90 degrees through the second rubber wheel 15, and then moving the next optical lens to the refracted projecting part, after the optical lenses on the placing disc 8 are coated, the electronic gun 10 and the motor 13 are closed, so that the coating of the optical lenses can be realized, then the sliding door 3 is opened again, the first sliding block 7 is pulled to move forwards, then the optical lenses on the placing disc 8 are turned over, the coating of the two surfaces of the optical lenses can be realized by repeating the operations, and after the coating is finished, the optical lenses can be taken out.

Example 2

In addition to embodiment 1, as shown in fig. 2, 5, 7, 8, 9 and 10, the locking mechanism 16 further includes a locking mechanism 16, the locking mechanism 16 includes a second rail 161, a second slider 162, a first spring 163, a diagonal block 164 and a second spring 165, the two second rails 161 are connected to the bottom of the inner side of the box 2 in a bolt connection manner, the two second rails 161 are bilaterally symmetrical, the second rail 161 is slidably connected with a second slider 162, the first spring 163 is connected between the second slider 162 and the second rail 161 in a lap joint manner, the diagonal block 164 for blocking the first slider 7 is slidably connected to the middle of the second slider 162, an inclined surface is provided on the front side of the diagonal block 164, and the second spring 165 is connected between the diagonal block 164 and the second slider 162.

The ramp block 164 initially blocks the first slider 7, limiting the position of the placing disk 8, preventing the first slider 7 from sliding on the first guide 6, when the first sliding block 7 needs to be moved forwards, the second sliding blocks 162 at the left and right sides are stirred to move towards the left and right sides respectively, the first spring 163 is compressed, the inclined block 164 moves along with the first spring, when the inclined block 164 does not block the first slide block 7, the first slide block 7 can be pulled to move forwards, and then the second slide blocks 162 at the two sides are released, the second slide block 162 is driven to reset under the action of the first spring 163, when the first slide block 7 needs to reset backwards, the first slide block 7 is pushed to move backwards, the second spring 165 is compressed by the first slider 7 pressing the slant blocks 164 at both sides away from each other, and when the first slider 7 moves to the rear of the slant blocks 164, the second spring 165 drives the ramp block 164 to return and block the first slider 7.

The box body 2 is characterized by further comprising a pushing mechanism 17, the pushing mechanism 17 comprises a second support 171, a rodless cylinder 172, a connecting block 173, a pushing block 174 and an inclined rod 175, the second support 171 is connected to the left side of the bottom in the box body 2, the rodless cylinder 172 is mounted on the second support 171, the connecting block 173 is connected to the rodless cylinder 172 in a bolt connection mode, the pushing block 174 is connected to the right side of the connecting block 173, the inclined rods 175 are connected to the left side and the right side of the rear portion of the pushing block 174, the inclined rods 175 are in a shape of a Chinese character 'ji', and the inclined rods 175 are in contact with the second sliding block 162.

When the placing disk 8 moves forward, the rodless cylinder 172 is started to move forward, the connecting block 173 drives the pushing block 174 to move forward, the inclined rod 175 pushes the second sliders 162 on the two sides to move away from each other, the first spring 163 is compressed, the inclined block 164 does not block the first slider 7, the pushing block 174 moves forward to contact with the first slider 7, the pushing block 174 pushes the first slider 7 to move forward, the placing disk 8 moves forward accordingly, when the placing disk 8 needs to be reset backward, the rodless cylinder 172 is started to move backward, the inclined rod 175 moves backward accordingly, the second slider 162 is driven to reset under the action of the first spring 163, then the first slider 7 is manually pushed to move backward, and the placing disk 8 moves backward accordingly.

Still including air exhaust mechanism 18, air exhaust mechanism 18 is including third extension board 181, air pump 182, exhaust tube 183 and blast pipe 184, the right side lower part of box 2 is connected with third extension board 181 through bolted connection's mode, install air pump 182 through bolted connection's mode on the third extension board 181, the inlet end of air pump 182 is connected with exhaust tube 183 through flange connection's mode, exhaust tube 183 runs through box 2 right wall, the end of giving vent to anger of air pump 182 is connected with blast pipe 184 through flange connection's mode.

When the optical lens is coated, the sliding door 3 is closed, then the air pump 182 is started to work, the air pump 182 works to pump out the air in the box body 2 through the air pumping pipe 183 and discharge the air through the exhaust pipe 184, so that the inside of the box body 2 is pumped into a high-vacuum coating cavity, then the air pump 182 is closed, and thus the optical lens is coated in the vacuum cavity, and the coating effect can be improved.

Example 3

Based on embodiment 2, as shown in fig. 2, 10, 11, 12, 13, 14, 15, 16 and 17, the present invention further includes a blanking mechanism 19, the blanking mechanism 19 includes a fourth support plate 191, a blanking frame 192 and a blanking tube 193, the fourth support plate 191 is connected to the upper portion of the rear side of the box body 2 in a bolt connection manner, the blanking frame 192 is connected to the top portion of the fourth support plate 191 in a welding connection manner, the lower portion of the blanking frame 192 penetrates through the rear side wall of the box body 2, the four blanking tubes 193 are connected to the bottom portion of the blanking frame 192, and the blanking tubes 193 are located above the eccentric position of the placing tray 8.

The quantitative mechanism 20 is further included, the quantitative mechanism 20 comprises an arc-shaped rack 201, an installation frame 202, a blocking block 203, a gear 204, a third support 205 and a torsion spring 206, the four arc-shaped racks 201 are evenly connected in the circumferential direction of the placing disc 8 at intervals, the installation frame 202 is connected to the middle portion of the inner rear wall of the box body 2 in a bolt connection mode, four discharge holes are formed in the front end of the installation frame 202 and are circular, the lower end of a discharge pipe 193 is in contact with the top of the installation frame 202 and is located right below the discharge pipe 193, the gear 204 is rotatably connected to the bottom of the front side of the installation frame 202, the arc-shaped racks 201 are meshed with the gear 204, the middle portion of the gear 204 is arranged in a hollow mode, the hollow portion of the gear 204 is connected with the cross-shaped blocking block 203 in a welding connection mode, a rubber block is arranged on the top of the blocking block 203 and is used for blocking the discharge holes, the upper portion of the front end of the installation frame 202 is connected with the third support 205, a torsion spring 206 is connected between the third bracket 205 and the putty piece 203.

Pouring the coating liquid into the blanking frame 192, wherein the coating liquid in the blanking frame 192 flows into the blanking pipe 193, at first, the lower end of the blanking pipe 193 is blocked by the blocking block 203, when the placing disc 8 rotates, the four arc-shaped racks 201 are driven to rotate, the arc-shaped racks 201 rotate to drive the gear 204 to rotate, the torsion spring 206 deforms, the blocking block 203 rotates along with the rotation of the blocking block 203, the lower end of the blanking pipe 193 is not blocked, the coating liquid in the blanking pipe 193 flows onto the optical lens on the placing disc 8, when the placing disc 8 rotates for 90 degrees, the arc-shaped racks 201 are separated from the gear 204, the gear 204 and the blocking block 203 are driven to reset under the action of the torsion spring 206, and the blanking pipe 193 is blocked again after the blocking block 203 resets. Therefore, the coating liquid can be automatically added, the coating liquid is not required to be manually coated on the optical lens, the labor intensity of workers is reduced, and the working efficiency is improved.

The sliding door is characterized by further comprising a sealing mechanism 21, wherein the sealing mechanism 21 comprises a rubber strip 211 and a magnet 212, the rubber strip 211 is connected to the right side of the sliding door 3 in a bolt connection mode, and the magnet 212 is connected to the front side of the left end face of the box body 2 in an embedded mode.

When sliding door 3 closed, can play sealed effect through rubber strip 211, make and form the high vacuum cavity in the box 2, avoid in the outside air gets into box 2, can hold the limiting plate of 3 left ends of sliding door through magnet 212 moreover, can fix sliding door 3, avoid sliding door 3 to remove.

The above examples are merely representative of preferred embodiments of the present invention, and the description thereof is more specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, various changes, modifications and substitutions can be made without departing from the spirit of the present invention, and these are all within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. A coating device for processing optical lenses is characterized by comprising a first support (1), a box body (2), a sliding door (3), a handle (4), a limiting block (5), a first guide rail (6), a first sliding block (7), a placing disc (8), a first support plate (9), an electron gun (10), a refractor (11), a second support plate (12), a motor (13), a first rubber wheel (14) and a second rubber wheel (15), wherein the left side and the right side of the lower part of the box body (2) are respectively connected with the first support (1), the front side of the box body (2) is glidingly connected with the sliding door (3), the right end of the front side of the sliding door (3) is connected with the handle (4), the right part of the front side of the sliding door (3) is connected with the limiting block (5), the inner bottom of the box body (2) is connected with the first guide rail (6), the first sliding block (7) is glidingly connected on the first guide rail (6), the upper end of the first sliding block (7) is rotatably connected with a placing disc (8), four placing grooves are formed in the top of the placing disc (8) in the circumferential direction at even intervals, the left side of the box body (2) is connected with a first support plate (9), an electron gun (10) is installed on the first support plate (9), a refractor (11) for receiving a light source of the electron gun (10) is connected to the right side of the top of the box body (2), a second support plate (12) is connected to the lower portion of the inner right side wall of the box body (2), a motor (13) is installed at the left end of the second support plate (12), a first rubber wheel (14) is connected to an output shaft of the motor (13), a second rubber wheel (15) is connected to the bottom of the placing disc (8), and the second rubber wheel (15) is in contact fit with the first rubber wheel (14); the blanking device is characterized by further comprising a blanking mechanism (19), wherein the blanking mechanism (19) comprises a fourth support plate (191), a blanking frame (192) and a blanking pipe (193), the fourth support plate (191) is connected to the upper portion of the rear side of the box body (2), the top of the fourth support plate (191) is connected with the blanking frame (192), the lower portion of the blanking frame (192) penetrates through the rear side wall of the box body (2), the bottom of the blanking frame (192) is connected with four blanking pipes (193), and the blanking pipe (193) is located above the eccentric position of the placing disc (8); the device is characterized by further comprising a quantifying mechanism (20), wherein the quantifying mechanism (20) comprises an arc-shaped rack (201), an installation frame (202), a blocking block (203), a gear (204), a third support (205) and a torsion spring (206), four arc-shaped racks (201) are uniformly connected to the circumferential direction of the placing disc (8) at intervals, the installation frame (202) is connected to the middle portion of the inner rear wall of the box body (2), four discharge holes are formed in the front end of the installation frame (202), the lower end of the discharging pipe (193) is in contact with the top of the installation frame (202), the discharge holes are located right below the discharging pipe (193), the gear (204) is rotatably connected to the bottom of the front side of the installation frame (202), the arc-shaped rack (201) is meshed with the gear (204), the middle of the gear (204) is hollow, the cross-shaped blocking block (203) is connected to the hollow portion of the gear (204), and the blocking block (203) is used for blocking the discharge holes, the upper part of the front end of the mounting rack (202) is connected with a third support (205), and a torsion spring (206) is connected between the third support (205) and the blocking block (203).

2. The coating device for processing the optical lens according to claim 1, further comprising a clamping mechanism (16), wherein the clamping mechanism (16) comprises a second guide rail (161), a second slider (162), a first spring (163), a diagonal block (164) and a second spring (165), the bottom of the inner side of the box body (2) is connected with the two second guide rails (161), the two second guide rails (161) are bilaterally symmetrical, the second guide rail (161) is slidably connected with the second slider (162), the first spring (163) is connected between the second slider (162) and the second guide rail (161), the middle of the second slider (162) is slidably connected with the diagonal block (164) for blocking the first slider (7), and the second spring (165) is connected between the diagonal block (164) and the second slider (162).

3. The coating device for processing the optical lens according to claim 2, further comprising a pushing mechanism (17), wherein the pushing mechanism (17) comprises a second bracket (171), a rodless cylinder (172), a connecting block (173), a pushing block (174) and an inclined rod (175), the second bracket (171) is connected to the left side of the bottom in the box body (2), the rodless cylinder (172) is mounted on the second bracket (171), the connecting block (173) is connected to the rodless cylinder (172), the pushing block (174) is connected to the right side of the connecting block (173), the inclined rod (175) is connected to both the left side and the right side of the rear of the pushing block (174), and the inclined rod (175) is in contact with the second slider (162).

4. The coating device for processing the optical lens as claimed in claim 3, further comprising an air pumping mechanism (18), wherein the air pumping mechanism (18) comprises a third support plate (181), an air pump (182), an air pumping pipe (183) and an air exhaust pipe (184), the third support plate (181) is connected to the lower portion of the right side of the box body (2), the air pump (182) is mounted on the third support plate (181), the air inlet end of the air pump (182) is connected to the air pumping pipe (183), the air pumping pipe (183) penetrates through the right wall of the box body (2), and the air outlet end of the air pump (182) is connected to the air exhaust pipe (184).

5. The coating device for processing the optical lens according to claim 4, further comprising a sealing mechanism (21), wherein the sealing mechanism (21) comprises a rubber strip (211) and a magnet (212), the rubber strip (211) is connected to the right side of the sliding door (3), and the magnet (212) is connected to the front side of the left end face of the box body (2) in an embedded manner.

6. The coating device for optical lens processing according to claim 1, wherein a limiting plate is disposed at the left end of the sliding door (3), and the limiting plate is made of iron.