CN115214154B

CN115214154B - Automatic gluing equipment for resin lens processing

Info

Publication number: CN115214154B
Application number: CN202210708596.5A
Authority: CN
Inventors: 南基学
Original assignee: Yejia Optical Technology Guangdong Corp
Current assignee: Yejia Optical Technology Guangdong Corp
Priority date: 2022-06-21
Filing date: 2022-06-21
Publication date: 2023-11-17
Anticipated expiration: 2042-06-21
Also published as: CN115214154A

Abstract

The application relates to the field of resin lenses, in particular to automatic gluing equipment for processing the resin lenses, which comprises a workbench, a linear driving assembly, a lens positioning assembly, a dispensing assembly and a driving motor, wherein the lens positioning assembly comprises a bottom plate, a first moving plate, a first spring, a second moving plate, a second spring, a limiting plate, a third moving plate and a third spring, the number of the lens positioning assemblies is two, the linear driving assembly is connected with the lens positioning assembly, the other linear driving assembly is a fixed lens positioning assembly, the dispensing assembly is arranged at a position, close to the fixed lens positioning assembly, on the workbench, and the driving motor is in transmission connection with the limiting plate in the fixed lens positioning assembly. According to the application, the functions that the two attached lenses can rotate when being glued are realized through the fixed lens positioning assembly, the movable lens positioning assembly, the glue dispensing assembly and the driving motor, so that glue can be fully spread on the attaching surfaces of the two lenses are realized.

Description

Automatic gluing equipment for resin lens processing

Technical Field

The application relates to the field of resin lenses, in particular to automatic gluing equipment for resin lens processing.

Background

Resin lenses are made of organic materials, resin lenses are gradually popularized in the market due to the good light transmittance, impact resistance and other capacities, the types of resin are mainly divided into natural resin and synthetic resin, at present, two lenses are manually placed and overlapped by workers in common resin lens processing on the market, then the two lenses are adjusted to finish centering work and then dispensing is carried out, but the workers can also bear certain operation risks while the overall working efficiency is slow due to the fact that the workers need to manually participate in the processing.

Chinese patent CN202111566187.8 discloses a veneer device for resin lens processing, accomplish the centering work of two lenses through movable plate and limiting plate, make two lenses be close to each other through movable plate and limiting plate's relative static, movable plate and limiting plate's relative slip make two lenses laminate each other, thereby make two lenses join in the place glue subassembly accomplish the veneer work, but this scheme is in the use because the position of lens and the position of some glue subassembly all remain fixed, thereby the glue that leads to some glue subassembly output only can flow slowly along the faying surface of lens, still there is the condition that unable abundant veneer between two lenses after the glue solidification to appear when the veneer rate is lower between two lenses.

Disclosure of Invention

Based on this, it is necessary to provide an automated gluing device for resin lens processing in order to solve the problems of the prior art.

In order to solve the problems in the prior art, the application adopts the following technical scheme:

the utility model provides an automatic gluing equipment for resin lens processing, comprises a workbench, the linear drive subassembly, the lens locating component, some glue subassembly and driving motor, the lens locating component includes the bottom plate, first movable plate, first spring, the second movable plate, the second spring, the limiting plate, third movable plate and third spring, the length direction of bottom plate and the direction of movement of linear drive subassembly are parallel, first movable plate and bottom plate sliding fit, first movable plate and the fixed cooperation of linear drive subassembly, the direction of sliding of first movable plate is parallel with the length direction of bottom plate, first spring sets up between bottom plate and first movable plate, the axis of first spring is parallel with the direction of sliding of first movable plate, second movable plate and first movable plate sliding fit, the direction of sliding of second movable plate is parallel with the width direction of bottom plate, all be connected with the second movable plate on the two sides that the first movable plate kept away from the bottom plate, the second spring is arranged between the first moving plate and the second moving plate, the axis of the second spring is parallel to the sliding direction of the second moving plate, the limiting plate is rotationally matched with the first moving plate, the limiting plate is rotationally arranged on one surface of the first moving plate, which is close to the center of the workbench, the third moving plate is in sliding fit with the bottom plate, the sliding direction of the third moving plate is parallel to the thickness direction of the bottom plate, the third moving plate is slidingly arranged on the side surface of the bottom plate, which is far away from the first moving plate, the third spring is arranged between the third moving plate and the bottom plate, the axis of the third spring is parallel to the sliding direction of the third moving plate, the number of lens positioning assemblies is two, the other lens positioning assembly is fixed, the bottom plate in the fixed lens positioning assembly is fixedly matched with the workbench, the first movable plate in the fixed lens positioning assembly is fixedly matched with the bottom plate, the dispensing assembly is arranged on the workbench and close to the position of the fixed lens positioning assembly, the driving motor is fixedly arranged on the workbench, and the driving motor is in transmission connection with the limiting plate in the fixed lens positioning assembly.

Preferably, the movable lens fixing assembly further comprises a first limit bolt, the first limit bolt is fixedly matched with the bottom plate, the first limit bolt is in sliding fit with the first movable plate, the axis of the first limit bolt is parallel to the sliding direction of the first movable plate, and the first spring is sleeved on the first limit bolt.

Preferably, the movable lens fixing assembly further comprises two limit nuts, the limit plates are provided with threaded rods matched with the limit nuts, and the threaded rods are movably matched with the first movable plate.

Preferably, the lens fixing assembly further comprises a second limit bolt, the second limit bolt is fixedly matched with the first moving plate, the second limit bolt is in sliding fit with the second moving plate, the axis of the second limit bolt is parallel to the sliding direction of the second moving plate, the second spring is sleeved on the second limit bolt, and the second spring is arranged on one surface, far away from the first moving plate, of the second moving plate.

Preferably, the second moving plate is provided with two second limit bolts in a sliding manner, and the two second limit bolts on the second moving plate are arranged in a mirror image manner.

Preferably, the second movable plate is in an isosceles trapezoid shape as a whole, the top surfaces of the two second movable plates are arranged in opposite directions, and the two inclined surfaces of the second movable plates face upwards and downwards respectively.

Preferably, the lens fixing assembly further comprises a third limit bolt, the third limit bolt is fixedly matched with the third moving plate, a limit long groove matched with the third limit bolt is formed in the bottom plate, and the length direction of the limit long groove is parallel to the sliding direction of the third moving plate.

Preferably, the lens fixing assembly further comprises a sliding block, the sliding block is arranged in the limiting long groove in a sliding mode, one end of the sliding block is arranged to be matched with the cambered surface of the third limiting bolt, and the third spring is arranged between the bottom plate and the sliding block.

Preferably, the side surface of the third movable plate far away from the bottom plate is provided with two fixing holes, the two fixing holes are uniformly arranged along the length direction of the third movable plate, the movable lens assembly further comprises a fixing block, and the fixing block is arranged in the fixing hole and extends to the outside of the third movable plate.

Preferably, the whole fixed block is trapezoidal, and the inclined plane of fixed block is towards the one end top that keeps away from the third stopper.

Compared with the prior art, the application has the beneficial effects that:

1. according to the application, the two lenses which are attached can rotate when being glued through the fixed lens positioning assembly, the movable lens positioning assembly, the glue dispensing assembly and the driving motor, so that glue can fully spread over the attaching surfaces of the two lenses, and the defect that glue output by the glue dispensing assembly only slowly flows along the attaching surfaces of the lenses due to the fact that the positions of the lenses and the positions of the glue dispensing assembly are kept fixed in the use process is overcome, so that the gluing rate between the two lenses is low, and meanwhile, the situation that the two lenses cannot be fully glued after the glue is solidified is also caused.

2. According to the application, the function of limiting the movement range of the first moving plate is realized through the first limiting bolt, and the defect that the first moving plate is possibly separated from the connection with the bottom plate when moving is overcome.

3. The application realizes the function of adjusting the position of the limiting plate through the limiting nut and the threaded rod, and solves the defect that the lens on the movable lens fixing assembly cannot be moved to the third movable plate due to the fact that the thickness of the lens is different.

4. According to the application, the function of limiting the moving direction of the second moving plate is realized through the second limiting bolt, and the defect that the second moving plate can move in the vertical direction in the moving process along with the linear driving assembly is overcome.

5. The application realizes the function of limiting the moving state of the second moving plate by limiting the number and the positions of the second limiting bolts, and solves the defect that the second moving plate can rotate when the lens rotates.

6. The application realizes the function that the second movable plate can guide the lens to move by limiting the shape of the second movable plate, and solves the defect that the lens possibly collides with the second movable plate when rotating again after rotating 180 degrees.

7. According to the application, the function of limiting the movement range of the third movable plate is realized through the third limiting bolt and the limiting long groove, and the defect that the third movable plate is possibly disconnected with the bottom plate after moving for a certain distance is overcome.

8. According to the application, the function of always keeping the elastic direction of the third spring stable is realized through the sliding block, and the defect that deflection is likely to occur when the third spring and the third limit bolt are matched for working is overcome.

9. According to the application, the function of synchronously moving the two third moving plates after the two third moving plates are contacted is realized through the fixing holes and the fixing blocks, and the defect that the two third moving plates are possibly non-uniform when moving is overcome.

10. The application realizes the function that the fixed block can be stably inserted into the fixed hole by limiting the shape of the fixed block, and solves the defect that the third moving plate moves a certain distance due to the weight of the lens when the lens exists on the fixed lens positioning component.

Drawings

FIG. 1 is a schematic perspective view of the overall movement process of the present application;

FIG. 2 is a front view of the overall movement process of the present application;

FIG. 3 is a schematic perspective view of the whole dispensing process of the present application;

FIG. 4 is a schematic perspective view of a fixed lens positioning assembly of the present application;

FIG. 5 is an exploded perspective view of the fixed lens positioning assembly of the present application;

FIG. 6 is a schematic perspective view of a mobile lens positioning assembly of the present application;

FIG. 7 is an exploded perspective view of the mobile lens positioning assembly of the present application;

FIG. 8 is a schematic perspective view of a base plate of the present application;

fig. 9 is a perspective view of a third moving plate of the present application;

fig. 10 is an exploded perspective view of a third moving plate of the present application.

The reference numerals in the figures are:

1-a workbench;

2-a linear drive assembly;

3-a lens positioning assembly; 3 a-a bottom plate; 3a 1-a limiting long groove; 3 b-a first moving plate; 3 c-a first spring; 3 d-a second moving plate; 3 e-a second spring; 3 f-limiting plates; 3f 1-a threaded rod; 3 g-a third moving plate; 3g 1-fixing holes; 3 h-a third spring; 3 i-a first limit bolt; 3 j-limit nuts; 3 k-a second limit bolt; 3 l-a third limit bolt; 3 m-sliders; 3 n-fixed block;

4-dispensing assembly;

5-driving a motor.

Detailed Description

The application will be further described in detail with reference to the drawings and the detailed description below, in order to further understand the features and technical means of the application and the specific objects and functions achieved.

As shown in fig. 1 to 10, the present application provides:

an automatic gluing device for resin lens processing comprises a workbench 1, a linear driving assembly 2, a lens positioning assembly 3, a dispensing assembly 4 and a driving motor 5, wherein the lens positioning assembly 3 comprises a bottom plate 3a, a first moving plate 3b, a first spring 3c, a second moving plate 3d, a second spring 3e, a limiting plate 3f, a third moving plate 3g and a third spring 3h, the length direction of the bottom plate 3a is parallel to the moving direction of the linear driving assembly 2, the first moving plate 3b is in sliding fit with the bottom plate 3a, the first moving plate 3b is fixedly matched with the linear driving assembly 2, the sliding direction of the first moving plate 3b is parallel to the length direction of the bottom plate 3a, a first spring 3c is arranged between the bottom plate 3a and the first moving plate 3b, the axis of the first spring 3c is parallel to the sliding direction of the first moving plate 3b, the second moving plate 3d is in sliding fit with the first moving plate 3b, the sliding direction of the second moving plate 3d is parallel to the width direction of the bottom plate 3a, the second moving plate 3d is connected to two side surfaces of the first moving plate 3b far away from the bottom plate 3a, a second spring 3e is arranged between the first moving plate 3b and the second moving plate 3d, the axis of the second spring 3e is parallel to the sliding direction of the second moving plate 3d, a limiting plate 3f is rotatably matched with the first moving plate 3b, the limiting plate 3f is rotatably arranged on one surface of the first moving plate 3b close to the center of the workbench 1, a third moving plate 3g is in sliding fit with the bottom plate 3a, the sliding direction of the third moving plate 3g is parallel to the thickness direction of the bottom plate 3a, a third moving plate 3g is arranged on the side surface of the bottom plate 3a far away from the first moving plate 3b in a sliding manner, a third spring 3h is arranged between the third moving plate 3g and the bottom plate 3a, the axis of the third spring 3h is parallel to the sliding direction of the third moving plate 3g, the number of lens positioning components 3 is two, the other is fixed lens locating component 3, a bottom plate 3a in the fixed lens locating component 3 is fixedly matched with the workbench 1, a first movable plate 3b in the fixed lens locating component 3 is fixedly matched with the bottom plate 3a, the dispensing component 4 is arranged on the workbench 1 and close to the position of the fixed lens locating component 3, a driving motor 5 is fixedly arranged on the workbench 1, and the driving motor 5 is in transmission connection with a limiting plate 3f in the fixed lens locating component 3.

Based on the above embodiment, the technical problem to be solved by the present application is that, in the use process, the positions of the lenses and the positions of the dispensing assembly 4 are kept fixed, so that the glue output by the dispensing assembly 4 can only slowly flow along the bonding surface of the lenses, the gluing rate between the two lenses is low, and meanwhile, the situation that the two lenses cannot be fully glued after the glue is solidified exists. Therefore, according to the application, one lens is placed on the fixed lens positioning component 3 and then the other lens is placed on the movable lens positioning component 3, at this time, the lens on the fixed lens positioning component 3 is placed on the third movable plate 3g under the action of the limiting plate 3f, the lens on the movable lens positioning component 3 is placed on the bottom plate 3a under the action of the limiting plate 3f, then the linear driving component 2 is operated to enable the movable lens positioning component 3 to approach the fixed lens positioning component 3, when the two third movable plates 3g are contacted, the limiting plate 3f on the movable lens positioning component 3 and the bottom plate 3a relatively slide to enable the two lenses to be attached on the third movable plate 3g, then the glue dispensing component 4 is operated to spray glue, and the driving motor 5 is operated to drive the two attached lenses to rotate so that the glue can fully surround the attaching surface.

Further, as shown in fig. 6 to 7:

the movable lens fixing assembly further comprises a first limit bolt 3i, the first limit bolt 3i is fixedly matched with the bottom plate 3a, the first limit bolt 3i is in sliding fit with the first movable plate 3b, the axis of the first limit bolt 3i is parallel to the sliding direction of the first movable plate 3b, and the first spring 3c is sleeved on the first limit bolt 3 i.

Based on the above embodiment, the technical problem to be solved by the present application is that the first moving plate 3b may be disconnected from the bottom plate 3a when moving. For this reason, the first moving plate 3b moves a certain distance and then contacts the end of the first stopper bolt 3i, and then stops moving, and the first stopper bolt 3i of the present application limits the moving range of the first moving plate 3b, compared with the prior art.

Further, as shown in fig. 6 to 7:

the movable lens fixing assembly further comprises limiting nuts 3j, the number of the limiting nuts 3j is two, threaded rods 3f1 matched with the limiting nuts 3j are arranged on the limiting plates 3f, and the threaded rods 3f1 are in movable fit with the first movable plates 3 b.

Based on the above-described embodiments, the technical problem to be solved by the present application is that the thickness of the lens is not uniform so that the lens on the moving lens fixing assembly cannot move onto the third moving plate 3 g. Therefore, compared with the prior art, the position of the limiting plate 3f can be adjusted by matching the limiting nut 3j with the threaded rod 3f 1.

Further, as shown in fig. 4 to 7:

the lens fixing assembly further comprises a second limit bolt 3k, the second limit bolt 3k is fixedly matched with the first movable plate 3b, the second limit bolt 3k is in sliding fit with the second movable plate 3d, the axis of the second limit bolt 3k is parallel to the sliding direction of the second movable plate 3d, a second spring 3e is sleeved on the second limit bolt 3k, and the second spring 3e is arranged on one surface, far away from the first movable plate 3b, of the second movable plate 3 d.

Based on the above embodiment, the technical problem to be solved by the present application is that the second moving plate 3d may move in the vertical direction during the movement along with the linear driving assembly 2. Therefore, the second limiting bolt 3k and the first moving plate 3b and the second moving plate 3d respectively ensure that the second moving plate 3d cannot move up and down, and compared with the prior art, the second limiting bolt 3k limits the moving direction of the second moving plate 3 d.

Further, as shown in fig. 4 to 7:

two second limit bolts 3k are slidably arranged on the second moving plate 3d, and the two second limit bolts 3k on the second moving plate 3d are arranged in a mirror image mode.

Based on the above embodiment, the technical problem to be solved by the present application is that the second moving plate 3d may also rotate when the lens rotates. For this reason, the present application provides a plurality of supporting points on the second moving plate 3d by providing a plurality of second limit bolts 3k, and the second moving plate 3d of the present application defines the moving state of the second moving plate 3d by defining the number and positions of the second limit bolts 3k, compared to the related art.

Further, as shown in fig. 4 to 7:

the second moving plates 3d are in an isosceles trapezoid shape as a whole, the top surfaces of the two second moving plates 3d are arranged in opposite directions, and two inclined surfaces of the second moving plates 3d face upwards and downwards respectively.

Based on the above embodiment, the technical problem to be solved by the present application is that the lens may collide with the second moving plate 3d after rotating 180 °. For this reason, the present application is to be brought into contact with the inclined surface first after the lens is rotated by a certain angle so as to be stably interposed between the two second moving plates 3d, and compared with the prior art, the second moving plates 3d of the present application are formed such that the second moving plates 3d can guide the movement of the lens by defining the shape.

Further, as shown in fig. 8 to 10:

the lens fixing assembly further comprises a third limit bolt 3l, the third limit bolt 3l is fixedly matched with the third movable plate 3g, a limit long groove 3a1 matched with the third limit bolt 3l is formed in the bottom plate 3a, and the length direction of the limit long groove 3a1 is parallel to the sliding direction of the third movable plate 3 g.

Based on the above embodiment, the technical problem to be solved by the present application is that the third moving plate 3g may be disconnected from the bottom plate 3a after moving a certain distance. Therefore, according to the application, after the third moving plate 3g moves a certain distance, the third limit bolt 3l contacts with the end of the limit long groove 3a1, so as to prevent the third moving plate 3g from moving continuously, compared with the prior art, the third limit bolt 3l and the limit long groove 3a1 limit the moving range of the third moving plate 3 g.

Further, as shown in fig. 8 to 10:

the lens fixing assembly further comprises a sliding block 3m, the sliding block 3m is arranged in the limiting long groove 3a1 in a sliding mode, one end of the sliding block 3m is arranged to be matched with the cambered surface of the third limiting bolt 3l, and the third spring 3h is arranged between the bottom plate 3a and the sliding block 3 m.

Based on the above embodiment, the technical problem to be solved by the present application is that the third spring 3h may be biased when working together with the third limit bolt 3 l. Therefore, the sliding block 3m replaces the third limit bolt 3l to be contacted with the third spring 3h to ensure the working stability of the third spring 3h, and compared with the prior art, the sliding block 3m of the application enables the elastic force direction of the third spring 3h to be always stable.

Further, as shown in fig. 9 to 10:

two fixed holes 3g1 are formed in the side surface, far away from the bottom plate 3a, of the third limiting plate 3f, the two fixed holes 3g1 are uniformly formed in the length direction of the third limiting plate 3f, the movable lens component further comprises a fixed block 3n, and the fixed block 3n is arranged in the fixed hole 3g1 and extends to the outside of the third limiting plate 3 f.

Based on the above embodiment, the technical problem to be solved by the present application is that the two third moving plates 3g may not be uniform when moving. For this reason, the present application completes the horizontal fixing of the position by the fixing block 3n being caught in the fixing hole 3g1 when the two third moving plates 3g are contacted, and compared with the prior art, the fixing hole 3g1 and the fixing block 3n of the present application allow the two third moving plates 3g to be synchronously moved after being contacted.

Further, as shown in fig. 9 to 10:

the whole fixed block 3n is trapezoidal, and the inclined plane of fixed block 3n is towards the one end top that keeps away from the third stopper.

Based on the above embodiment, the technical problem to be solved by the present application is that the third moving plate 3g moves a certain distance due to the weight of the lens when the lens is present on the fixed lens positioning assembly 3. For this reason, the present application guides the two third moving plates 3g to be kept horizontal by the presence of the inclined surface when the fixing block 3n on the moving lens positioning assembly 3 contacts the fixing hole 3g1 on the fixing lens positioning assembly 3, and compared with the prior art, the fixing block 3n of the present application ensures that the fixing block 3n can be stably inserted into the fixing hole 3g1 by defining the shape.

The foregoing examples merely illustrate one or more embodiments of the application, which are described in greater detail and are not to be construed as limiting the scope of the application. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the application, which are all within the scope of the application. Accordingly, the scope of protection of the present application is to be determined by the appended claims.

Claims

1. An automatic gluing device for resin lens processing comprises a workbench (1), a linear driving assembly (2), a lens positioning assembly (3), a dispensing assembly (4) and a driving motor (5), and is characterized in that,

the lens positioning component (3) comprises a bottom plate (3 a), a first moving plate (3 b), a first spring (3 c), a second moving plate (3 d), a second spring (3 e), a limiting plate (3 f), a third moving plate (3 g) and a third spring (3 h), wherein the length direction of the bottom plate (3 a) is parallel to the moving direction of the linear driving component (2), the first moving plate (3 b) is in sliding fit with the bottom plate (3 a), the first moving plate (3 b) is fixedly matched with the linear driving component (2), the sliding direction of the first moving plate (3 b) is parallel to the length direction of the bottom plate (3 a), the first spring (3 c) is arranged between the bottom plate (3 a) and the first moving plate (3 b), the axis of the first spring (3 c) is parallel to the sliding direction of the first moving plate (3 b), the sliding direction of the second moving plate (3 d) is parallel to the width direction of the bottom plate (3 a), the first moving plate (3 b) is far away from the second spring (3 e) and the second moving plate (3 d) is arranged between the second spring (3 d) and the second moving plate (3 e), the limiting plate (3 f) is in rotary fit with the first moving plate (3 b), the limiting plate (3 f) is rotatably arranged on one surface of the first moving plate (3 b) close to the center of the workbench (1), the third moving plate (3 g) is in sliding fit with the bottom plate (3 a), the sliding direction of the third moving plate (3 g) is parallel to the thickness direction of the bottom plate (3 a), the third moving plate (3 g) is arranged on the side surface, far away from the first moving plate (3 b), of the bottom plate (3 a), the third spring (3 h) is arranged between the third moving plate (3 g) and the bottom plate (3 a), and the axis of the third spring (3 h) is parallel to the sliding direction of the third moving plate (3 g);

the number of the lens positioning assemblies (3) is two, the movable lens positioning assemblies (3) are connected with the linear driving assembly (2), and the other fixed lens positioning assemblies (3);

a bottom plate (3 a) in the fixed lens positioning assembly (3) is fixedly matched with the workbench (1), and a first moving plate (3 b) in the fixed lens positioning assembly (3) is fixedly matched with the bottom plate (3 a);

the dispensing component (4) is arranged on the workbench (1) at a position close to the fixed lens positioning component (3);

the driving motor (5) is fixedly arranged on the workbench (1), and the driving motor (5) is in transmission connection with the limiting plate (3 f) in the fixed lens positioning assembly (3).

2. An automated bonding apparatus for resin lens processing according to claim 1, wherein the movable lens fixing assembly further comprises a first limit bolt (3 i);

the first limiting bolt (3 i) is fixedly matched with the bottom plate (3 a), the first limiting bolt (3 i) is in sliding fit with the first moving plate (3 b), the axis of the first limiting bolt (3 i) is parallel to the sliding direction of the first moving plate (3 b), and the first spring (3 c) is sleeved on the first limiting bolt (3 i).

3. An automated bonding apparatus for resin lens processing according to claim 2, wherein the movable lens fixing assembly further comprises a limit nut (3 j);

the number of the limit nuts (3 j) is two, a threaded rod (3 f 1) matched with the limit nuts (3 j) is arranged on the limit plate (3 f), and the threaded rod (3 f 1) is movably matched with the first movable plate (3 b).

4. An automated bonding apparatus for resin lens processing according to claim 3, wherein the lens fixing assembly further comprises a second limit bolt (3 k);

the second limit bolt (3 k) is fixedly matched with the first movable plate (3 b), the second limit bolt (3 k) is in sliding fit with the second movable plate (3 d), the axis of the second limit bolt (3 k) is parallel to the sliding direction of the second movable plate (3 d), the second spring (3 e) is sleeved on the second limit bolt (3 k), and the second spring (3 e) is arranged on one surface, far away from the first movable plate (3 b), of the second movable plate (3 d).

5. The automated bonding equipment for resin lens processing according to claim 4, wherein two second limit bolts (3 k) are slidably disposed on the second moving plate (3 d), and the two second limit bolts (3 k) on the second moving plate (3 d) are mirror-image-disposed.

6. The automated bonding apparatus for resin lens processing according to claim 5, wherein the second moving plates (3 d) are formed in an isosceles trapezoid shape as a whole, top surfaces of the two second moving plates (3 d) are disposed opposite to each other, and two inclined surfaces of the second moving plates (3 d) are directed upward and downward, respectively.

7. An automated bonding apparatus for resin lens processing according to claim 6, wherein the lens fixing assembly further comprises a third limit bolt (3 l);

the third limit bolt (3 l) is fixedly matched with the third movable plate (3 g), a limit long groove (3 a 1) matched with the third limit bolt (3 l) is formed in the bottom plate (3 a), and the length direction of the limit long groove (3 a 1) is parallel to the sliding direction of the third movable plate (3 g).

8. An automated bonding apparatus for resin lens processing according to claim 7, wherein the lens fixing assembly further comprises a slide (3 m);

the sliding block (3 m) is arranged in the limiting long groove (3 a 1) in a sliding mode, one end of the sliding block (3 m) is arranged to be matched with the cambered surface of the third limiting bolt (3 l), and the third spring (3 h) is arranged between the bottom plate (3 a) and the sliding block (3 m).

9. An automated bonding apparatus for resin lens processing according to claim 8, wherein the side of the third moving plate (3 g) remote from the bottom plate (3 a) is provided with two fixing holes (3 g 1);

the two fixing holes (3 g 1) are uniformly formed along the length direction of the third moving plate (3 g), the moving lens assembly further comprises a fixing block (3 n), and the fixing block (3 n) is arranged in the fixing hole (3 g 1) and extends to the outside of the third moving plate (3 g).

10. The automated bonding equipment for resin lens processing according to claim 9, wherein the fixing block (3 n) is integrally trapezoidal, and the inclined surface of the fixing block (3 n) faces upward toward one end far from the third stopper.