CN114619690A - Lens equipment circulation production line - Google Patents

Abstract

The invention belongs to the technical field of conveying, and particularly relates to a lens assembling and circulating production line, which comprises: the device comprises a feeding conveying mechanism, an assembling conveying mechanism, two transferring mechanisms and a detecting mechanism; the two transfer mechanisms are respectively connected with the end parts of the feeding conveying mechanism and the assembling conveying mechanism to form a conveying loop, a plurality of carrying plates are arranged on the conveying loop, a plurality of assembling mechanisms are arranged on one side of the assembling conveying mechanism, each assembling mechanism is connected with the assembling conveying mechanism, and the detection mechanism is arranged at the tail end of the last stage of assembling mechanism; each carrying plate circularly rotates on the conveying loop; when the carrying plate rotates to the feeding conveying mechanism, the carrying plate receives the lens to be assembled; when the object carrying plate receiving the lens to be assembled is transferred to the assembling and conveying mechanism, the object carrying plate sequentially enters each assembling mechanism; and the detection mechanism receives and detects the assembled lens.

Description

Lens equipment circulation production line

Technical Field

The invention belongs to the technical field of conveying, and particularly relates to a lens assembling and circulating production line.

Background

In the production process of the lens, a plurality of assembling processes are required from one substrate to the completion of assembly, one process is usually performed by one operator, and the assembly is completed by the cooperation of a plurality of operators.

However, the lens is transferred from one process to another process, manual conveying is needed, and a large number of lenses are conveyed at the same time, so that the method is not only labor-consuming, but also easy to damage the lenses.

Disclosure of Invention

The invention aims to provide a lens assembly cycle production line.

In order to solve the above technical problems, the present invention provides a lens assembly cycle production line, which includes: the device comprises a feeding conveying mechanism, an assembling conveying mechanism, two transferring mechanisms and a detecting mechanism; the two transfer mechanisms are respectively connected with the end parts of the feeding conveying mechanism and the assembling conveying mechanism to form a conveying loop, a plurality of carrying plates are arranged on the conveying loop, a plurality of assembling mechanisms are arranged on one side of the assembling conveying mechanism, each assembling mechanism is connected with the assembling conveying mechanism, and the detection mechanism is arranged at the tail end of the last stage of assembling mechanism; each carrying plate circularly rotates on the conveying loop; when the carrying plate is rotated to the feeding conveying mechanism, the carrying plate receives the lens to be assembled; when the carrying plate which receives the lens to be assembled is transferred to the assembling and conveying mechanism, the carrying plate sequentially enters each assembling mechanism; and the detection mechanism receives and detects the assembled lens.

In one embodiment, the feeding conveyor mechanism includes: a first conveyor line; the assembly conveying mechanism comprises: a second conveyor line; first transfer chain, second transfer chain parallel arrangement, and direction of delivery is reverse to be set up.

In one embodiment, the transfer mechanism comprises: the device comprises a track and a first pushing assembly arranged at one end of the track; the two tracks are respectively connected with the ends of the first conveying line and the second conveying line to form the conveying loop; the two first pushing assemblies are respectively arranged on the first conveying line and the second conveying line; when the first pushing assembly receives the loading plate, the first pushing assembly pushes the loading plate to the other end of the track.

In one embodiment, the assembly mechanism comprises: the assembly table and the second pushing assembly; the assembly table is connected with the second pushing assembly; when the second pushing assembly receives the object carrying plate, the second pushing assembly pushes the object carrying plate to the assembling table.

In one embodiment, a sliding groove is formed on the table surface of the assembling table.

In one embodiment, the first pushing assembly and the second pushing assembly each include: the device comprises a mounting frame, a pulley block and a driving motor; the pulley block is arranged on the mounting rack; the driving motor drives the pulley block to rotate so as to push the carrying plate.

In one embodiment, the driving motor is a servo motor.

In one embodiment, the rotation direction of the pulley block is perpendicular to the conveying direction of the corresponding conveying line.

In one embodiment, a belt is sleeved on the periphery of the pulley block.

In one embodiment, the detection mechanism comprises: the device comprises a guide plate, a composite plate, a cleaning liquid coating mechanism assembly, a hoisting reset mechanism assembly, a cleaning pool and a second alarm assembly; the cleaning device comprises a conveying mechanism, a composite board, a lifting reset mechanism assembly, a cleaning solution coating mechanism assembly, a cleaning pool and a second alarm assembly, wherein the guide plate is positioned between the conveying mechanism and the composite board, a rotating shaft is arranged in the middle of the composite board, a lens accommodating groove is formed in one end, facing the conveying mechanism, of the composite board, a first convex edge is arranged at an inlet of the lens accommodating groove, the lifting reset mechanism assembly is arranged above the composite board and is connected with one end, provided with the lens accommodating groove, of the composite board, the cleaning solution coating mechanism assembly is arranged in the composite board, the coating end of the cleaning solution coating mechanism assembly extends into the lens accommodating groove, the cleaning pool is positioned below the composite board, and the second alarm assembly is arranged in the lens accommodating groove; when the guide plate receives lenses of a first specification, the lenses of the first specification slide into the lens containing groove, the lower surface of the lenses of the first specification is cleaned by the first convex edge, meanwhile, the front end of the lenses of the first specification is guided to stick up and press the coating end of the cleaning liquid coating mechanism assembly so that the cleaning liquid coating mechanism assembly seeps out the cleaning liquid, the end part of the composite plate is stressed to overcome the pulling force of the hoisting reset mechanism assembly and then rotates downwards around the rotating shaft, the lenses of the first specification coated with the cleaning liquid slide out of the lens containing groove and fall into the cleaning pool, and the hoisting reset mechanism assembly drives the composite plate to reset; when the deflector receives the third specification lens, the third specification lens slides into the lens holding tank, the lower surface of the clean third specification lens of first bead leads the first bead of gliding after the front end perk of third specification lens simultaneously, the second warning subassembly is reported to the police after continuously receiving the pressure of third specification lens.

The invention has the advantages that the two transfer mechanisms are arranged to connect the feeding conveying mechanism and the assembling conveying mechanism into a conveying loop, so that each object carrying plate is circularly conveyed in the conveying loop, namely, the object carrying plate receives the lens to be assembled on the feeding conveying mechanism, the lens is assembled at each assembling mechanism of the assembling conveying mechanism, the assembled lens is conveyed into the detection mechanism by the manipulator to be detected, and the empty object carrying plate returns to the feeding conveying mechanism to receive the lens to be assembled, so that the circular production is formed, and the production efficiency is greatly improved.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and drawings.

In order to make the aforementioned and other objects, features and advantages of the present invention comprehensible, preferred embodiments accompanied with figures are described in detail below.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a schematic view of the lens assembly cycle line of the present invention;

FIG. 2 is a schematic structural view of the pushing assembly of the present invention;

FIG. 3 is a schematic view of the structure of the detection mechanism of the present invention;

fig. 4 is a schematic structural view of the composite panel of the present invention.

In the figure:

1. a feeding conveyor mechanism; 11. a first conveyor line; 2. assembling a conveying mechanism; 21. a second conveyor line; 3. a transfer mechanism; 31. a track; 32. a first pushing assembly; 4. a detection mechanism; 41. a guide plate; 42. a composite board; 421. a first rotating shaft; 422. a lens receiving groove; 423. a first rib; 424. a first buffer spring group; 43. a cleaning solution application mechanism assembly; 431. a cleaning fluid storage chamber; 432. a coating section; 4321. a second rib; 4322. a second buffer spring group; 4323. a plugging plate; 4324. a third buffer spring group; 433. a guide roller; 44. hoisting a resetting mechanism component; 441. a fixing plate; 442. a magnetic plate; 443. a second rotating shaft; 444. a connecting plate; 45. a cleaning tank; 451. a carrying net; 452. an ultrasonic generator; 46. a first alarm assembly; 461. a position sensor; 47. a second alarm assembly; 471. a pressure sensor; 48. coating the end; 5. a loading plate; 6. an assembly mechanism; 61. an assembly table; 611. a chute; 62. a second pushing assembly; 621. a mounting frame; 622. and (4) a pulley block.

Detailed Description

To make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

As shown in fig. 1, the present embodiment provides a lens assembly cycle production line, which includes: the device comprises a feeding conveying mechanism 1, an assembling conveying mechanism 2, two transfer mechanisms 3 and a detection mechanism 4; the two transfer mechanisms 3 are respectively connected with the end parts of the feeding conveying mechanism 1 and the assembling conveying mechanism 2 to form a conveying loop, a plurality of carrying plates 5 are arranged on the conveying loop, a plurality of assembling mechanisms 6 are arranged on one side of the assembling conveying mechanism 2, each assembling mechanism 6 is connected with the assembling conveying mechanism 2, and the detection mechanism 4 is arranged at the tail end of the last-stage assembling mechanism 6; each carrying plate 5 circularly rotates on the conveying loop; when the carrying plate 5 rotates to the feeding mechanism 1, the carrying plate 5 receives the lens to be assembled; when the carrying plate 5 receiving the lens to be assembled is transferred to the assembling and conveying mechanism 2, the carrying plate sequentially enters each assembling mechanism 6; the detection mechanism 4 receives and detects the assembled lens.

In the embodiment, the two transfer mechanisms 3 connect the feeding conveying mechanism 1 and the assembling conveying mechanism 2 into a conveying loop, so that each carrying plate 5 is circularly conveyed in the conveying loop, that is, the carrying plate 5 receives the lens to be assembled on the feeding conveying mechanism 1, the lens is assembled at each assembling mechanism 6 of the assembling conveying mechanism 2, the assembled lens is conveyed into the detection mechanism 4 by a manipulator for detection, and the empty carrying plate 5 returns to the feeding conveying mechanism 1 to receive the lens to be assembled, so that circular production is formed, and the production efficiency is greatly improved.

In this embodiment, the feeding conveyor mechanism 1 includes: a first conveyance line 11; the assembly conveying mechanism 2 includes: a second conveyance line 21; the first conveying line 11 and the second conveying line 21 are arranged in parallel, and the conveying directions are arranged in opposite directions.

In the present embodiment, the first conveyor line 11 and the second conveyor line 21 are provided in opposite conveying directions, and the carrier plates 5 are moved in one conveying direction in cooperation with the corresponding transfer mechanisms 3.

In the present embodiment, the transfer mechanism 3 includes: a track 31 and a first pushing assembly 32 arranged at one end of the track 31; wherein the two rails 31 are respectively connected with the ends of the first conveying line 11 and the second conveying line 21 to form the conveying loop; the two first pushing assemblies 32 are respectively arranged on the first conveying line 11 and the second conveying line 21; when the first pushing assembly 32 receives the object carrying plate 5, the first pushing assembly 32 pushes the object carrying plate 5 to the other end of the track 31.

In this embodiment, the first pushing module 32 on the first conveyor line 11 receives the object plate 5 and then pushes the object plate 5 onto the second conveyor line 21, and the first pushing module 32 on the second conveyor line 21 receives the object plate 5 and then pushes the object plate 5 onto the first conveyor line 11, so as to form a circulation loop.

In the present embodiment, the fitting mechanism 6 includes: an assembly table 61 and a second pusher assembly 62; wherein the second pushing assembly 62 is arranged on the second conveying line 21, and the assembling table 61 is connected with the second pushing assembly 62; when the second pushing assembly 62 receives the object plate 5, the second pushing assembly 62 pushes the object plate 5 to the assembling table 61.

In the present embodiment, each assembling mechanism 6 sequentially assembles the lenses step by step; second propelling movement subassembly 62 receives to carry thing board 5 after, will carry thing board 5 propelling movement to go up assembly table 61, and the operative employee of assembly table 61 department assembles the lens on carrying thing board 5, and the operative employee pushes back second propelling movement subassembly 62 with carrying thing board 5 after the assembly is accomplished, makes to carry thing board 5 and gets into next assembly devices 6 and carries out follow-up assembly to improve assembly efficiency.

In this embodiment, the table surface of the mounting table 61 is provided with a sliding groove 611.

In the present embodiment, the sliding groove 611 facilitates the movement of the loading plate 5 and also serves to guide the movement of the loading plate 5.

As shown in fig. 2, in the present embodiment, the first pushing assembly 32 and the second pushing assembly 62 each include: the mounting frame 621, the pulley block 622 and the driving motor; the mounting rack 621 is connected with a corresponding conveying line, and the pulley block 622 is arranged on the mounting rack 621; the driving motor drives the pulley block 622 to rotate so as to push the carrying plate 5.

In this embodiment, the driving motor is a servo motor.

In this embodiment, the rotation direction of the pulley block 622 is perpendicular to the conveying direction of the second conveying line 21.

In this embodiment, a belt is sleeved on the periphery of the pulley block 622.

In this embodiment, the belt is elevated above the mounting block 621 for receiving the carrier plate 5; the conveying direction of the pulley block 622 is perpendicular to the conveying direction of the corresponding conveying line, so that the carrying plate 5 is pushed away from the corresponding conveying line; the servo motor can control the rotation direction of the pulley block 622 to form conveying loops in different conveying directions, and can control the switch of the pulley block 622 to adapt to different numbers of operators.

As shown in fig. 3 and 4, in the present embodiment, the detection mechanism 4 includes: the device comprises a guide plate 41, a composite plate 42, a cleaning liquid coating mechanism assembly 43, a hoisting reset mechanism assembly 44, a cleaning pool 45, a first alarm assembly 46 and a second alarm assembly 47; the guide plate 41 is located between the conveying mechanism and the composite plate 42, the middle of the composite plate 42 is provided with a first rotating shaft 421, one end, facing the conveying mechanism, of the composite plate 42 is provided with a lens accommodating groove 422, an inlet of the lens accommodating groove 422 is provided with a first convex rib 423, the hoisting and resetting mechanism assembly 44 is arranged above the composite plate 42 and is connected with one end, provided with the lens accommodating groove 422, of the composite plate 42, the cleaning liquid coating mechanism assembly 43 is arranged inside the composite plate 42, a coating end 48 of the cleaning liquid coating mechanism assembly extends into the lens accommodating groove 422, the cleaning pool 45 is located below the composite plate 42, the first alarm assembly 46 is arranged on the hoisting and resetting mechanism assembly 44, and the second alarm assembly 47 is arranged inside the lens accommodating groove 422; when the guide plate 41 receives the lenses of the first specification, the lenses of the first specification slide into the lens holding groove 422, the first convex ridge 423 cleans the lower surface of the lenses of the first specification and guides the front end of the lenses of the first specification to tilt and press the coating end 48 of the cleaning liquid coating mechanism assembly 43 so that the cleaning liquid coating mechanism assembly 43 seeps out the cleaning liquid, and the end of the composite plate 42 is stressed to overcome the pulling force of the hoisting reset mechanism assembly 44 and then rotates downwards around the first rotating shaft 421, so that the lenses of the first specification coated with the cleaning liquid slide out of the lens holding groove 422 and fall into the cleaning pool 45, and the hoisting reset mechanism assembly 44 drives the composite plate 42 to reset; when the guide plate 41 receives lenses of a second specification, the lenses of the second specification slide into the lens accommodating grooves 422, the first convex ribs 423 clean the lower surfaces of the lenses of the second specification and guide the front ends of the lenses of the second specification to tilt up and press against the coating ends 48 of the cleaning liquid coating mechanism assemblies 43 so that the cleaning liquid coating mechanism assemblies 43 seep out cleaning liquid, the end portions of the composite plates 42 are stressed to overcome the tensile force of the hoisting reset mechanism assemblies 44 and then rotate downwards around the first rotating shaft 421, the first convex ribs 423 and the coating ends 48 of the cleaning liquid coating mechanism assemblies 43 clamp the lenses of the second specification, and the first alarm assembly 46 detects that the hoisting reset mechanism assemblies 44 continue to be stretched and then gives an alarm; when the guide plate 41 receives the lenses of the third specification, the lenses of the third specification slide into the lens accommodating grooves 422, the lower surface of the lens of the third specification cleaned by the first rib 423 guides the front end of the lens of the third specification to tilt and then slide through the first rib 423, and the second alarm component 47 continuously gives an alarm after receiving the pressure of the lens of the third specification.

In this embodiment, the first specification lens is a qualified lens, the second specification lens is an over-thick lens, and the third specification lens is an over-thin lens, and the lenses of the specifications have only thickness differences.

Guide plate 41

The first specification lens, the second specification lens and the third specification lens slide into the lens accommodating groove 422 of the composite plate 42 through the guide plate 41; the first, second, and third specification lenses can be moved from the carrier plate to the guide plate 41 by a robot.

Lens holding groove 422

The lens holding groove 422 of the composite plate 42 mainly functions to receive lenses of the first specification, lenses of the second specification, and lenses of the third specification; when the lens containing groove 422 receives a lens of a first specification, the composite plate 42 is matched with the cleaning solution coating mechanism assembly 43 and the hoisting reset mechanism assembly 44, and the lens of the first specification is coated with the cleaning solution and then guided to slide into the cleaning pool 45 for cleaning; when the lens holding groove 422 receives a lens of a second specification, the composite plate 42 is matched with the cleaning solution coating mechanism assembly 43, the hoisting reset mechanism assembly 44 and the first alarm assembly 46, so that the lens of the second specification is clamped in the lens holding groove 422 and an alarm is given; when the lens accommodating groove 422 receives the lens of the third specification, the composite board 42 is matched with the hoisting reset mechanism component 44 and the second alarm component 47, so that the lens of the third specification stays in the lens accommodating groove 422 and an alarm is given.

Hoist and mount canceling release mechanical system subassembly 44

The hoisting reset mechanism assembly 44 mainly plays a role in resetting the rotated composite board 42 and also plays a role in screening lenses of a first specification, lenses of a second specification and lenses of a third specification; when the first specification lens enters the lens holding groove 422, the end of the composite board 42 carrying the first specification lens is stressed to overcome the tension of the lifting reset mechanism assembly 44 and then rotates; when the second specification lens enters the lens holding groove 422, the end of the composite board 42 carrying the second specification lens is stressed to overcome the tension of the lifting reset mechanism assembly 44 and then rotates; when the third size lens enters the lens receiving groove 422, the composite plate 42 does not rotate.

Cleaning solution application mechanism assembly 43

The cleaning solution coating mechanism assembly 43 mainly plays a role in coating the cleaning solution on the first specification lens and the second specification lens, and after the third specification lens enters the lens accommodating groove 422, the third specification lens cannot trigger the cleaning solution coating mechanism assembly 43, that is, the cleaning solution coating mechanism assembly 43 does not seep out the cleaning solution.

First rib 423

The first rib 423 is transversely disposed on the moving path of the lenses, and mainly plays a role of lifting the front ends of the lenses of the first specification, the lenses of the second specification, and the lenses of the third specification, so that the lenses of the first specification and the lenses of the second specification are pressed against the coating end 48 of the cleaning solution coating mechanism assembly 43 to seep out the cleaning solution.

In this embodiment, a first buffer spring group 424 is disposed on a lower end surface of the first rib 423; the first rib 423 is connected to the inner wall of the lens receiving groove 422 by the first buffer spring group 424.

In the present embodiment, the first rib 423 cleans the lower surface of each specification of lenses during the process of lifting each specification of lenses; after being lifted, each specification lens slides through the first rib 423, and the first rib 423 presses the first buffer spring group 424 downwards under the force so that each specification lens slides; after the first specification lenses slide through the first rib 423, the composite plate 42 slides out of the first rib 423 after being forced to rotate; after the second specification lenses slide through the first rib 423, the composite plate 42 is forced to rotate, and the second specification lenses are extruded by the first rib 423 and the coating end 48 of the cleaning liquid coating mechanism assembly 43 due to the excessive thickness of the second specification lenses so as to be clamped in the lens holding grooves 422; when the third gauge lens slides past the first rib 423, the composite plate 42 is not subjected to sufficient force to rotate.

In this embodiment, the cleaning liquid applying mechanism assembly 43 includes: a cleaning liquid storage chamber 431 and an applying portion 432; wherein the cleaning solution storage chamber 431 is disposed above the lens receiving groove 422, a waist-shaped hole is disposed between the cleaning solution storage chamber 431 and the lens receiving groove 422, and the coating portion 432 is disposed in the waist-shaped hole; the coating portion 432 includes: the second rib 4321, the second buffer spring group 4322, the blocking plate 4323 and the third buffer spring group 4324; the blocking plate 4323 is disposed in the cleaning solution storage chamber 431, the second protruding rib 4321 is disposed in the lens accommodating groove 422, two ends of the second buffer spring group 4322 are respectively connected to the second protruding rib 4321 and the blocking plate 4323, and two ends of the third buffer spring group 4324 are respectively connected to the blocking plate 4323 and the upper inner wall of the cleaning solution storage chamber 431; the second rib 4321 is forced to rise, and the second buffer spring set 4322 drives the blocking plate 4323 to rise to open the kidney-shaped hole, so that the cleaning solution seeps out.

In the present embodiment, when the front ends of the first specification lens and the second specification lens are lifted by the first rib 423 and then pushed against the coating end 48 of the cleaning solution coating mechanism assembly 43, the cleaning solution in the cleaning solution coating mechanism assembly 43 falls on the upper surfaces of the first specification lens and the second specification lens, and when the front end of the third specification lens is lifted by the first rib 423, the front end of the third specification lens cannot touch the coating end 48 of the cleaning solution coating mechanism assembly 43 because the thickness of the third specification lens is too thin, that is, the cleaning solution is not coated.

As shown, in this embodiment, the hoist reset mechanism assembly 44 includes: a fixed plate 441, a magnetic plate 442, a second rotation shaft 443, a connection plate 444, and a return spring; one end of the magnetic plate 442 is connected to the fixing plate 441 via a second rotating shaft 443, the other end of the magnetic plate is connected to the end of the composite plate 42, where the lens accommodating groove 422 is formed, via the connecting plate 444, and the return spring is sleeved on the second rotating shaft 443; the two ends of the connecting plate 444 are respectively connected with the magnetic plate 442 and the composite plate 42 in a rotating manner; when the lens accommodating groove 422 of the composite plate 42 receives the first specification lens and the second specification lens, the composite plate 42 rotates around the second rotation axis 443, that is, the magnetic plate 442 is driven by the connecting plate 444 to rotate around the second rotation axis 443; when the first specification lens and the second specification lens in the lens accommodating groove 422 are moved out, the return spring drives the magnetic plate 442 to return, that is, the composite plate 42 returns.

In this embodiment, the fixing plate 441 is fixedly disposed on the bracket, and when the lens accommodating groove 422 receives the lenses of the first and second specifications, the composite plate 42 applies a pulling force to the magnetic plate 442, so that the magnetic plate 442 overcomes the magnetic force and the force of the return spring to rotate, that is, the composite plate 42 rotates downward; when the lens receiving groove 422 receives a lens of the third specification, the composite plate 42 exerts a pulling force on the magnetic plate 442 that is insufficient to cause the magnetic plate 442 to overcome the magnetic force and the force of the return spring, i.e., the composite plate 42 does not rotate.

In this embodiment, the first alarm assembly 46 includes: a position sensor 461 and a first alarm; the position sensor 461 is arranged on the fixing plate 441, and the first alarm is electrically connected with the position sensor 461; when the position sensor 461 detects that the magnetic plate 442 is continuously opened, a signal is transmitted to the first alarm, that is, the first alarm sends out an alarm signal.

In this embodiment, after the first alarm sends out the alarm signal, the worker takes out the second specification lens in the lens receiving groove 422 to reset the magnetic plate 442.

In this embodiment, the second alarm component 47 includes: a pressure sensor 471 and a second alarm; the pressure sensor 471 is disposed on the lower inner wall of the lens receiving groove 422, and the second alarm is electrically connected to the pressure sensor 471; after the third specification lens enters the lens accommodating groove 422, the composite plate 42 keeps balanced, and the second alarm alarms when detecting that the pressure sensor 471 is continuously pressed.

In this embodiment, after the second alarm alarms, the worker takes out the third specification lenses in the lens accommodating groove 422 to release the alarm.

In this embodiment, the guide roller 433 is disposed on a side of the second protruding rib 4321 away from the entrance of the lens accommodating groove 422; the guide roller 433 evenly scrapes the cleaning liquid on the first specification lens and the second specification lens.

In this embodiment, a carrying net 451 and an ultrasonic generator 452 are disposed in the cleaning tank 45; the ultrasonic generator 452 is arranged on the inner wall of the cleaning tank 45, and the carrying net 451 is sleeved in the cleaning tank 45; the ultrasonic generator 452 cleans the first specification lenses in the carrier net 451.

In this embodiment, the carrier net 451 facilitates collection of the first format lenses, enabling quick collection thereof after cleaning.

In summary, the invention connects the feeding conveying mechanism 1 and the assembling conveying mechanism 2 into a conveying loop by arranging the two transfer mechanisms 3, so that each object carrying plate 5 is circularly conveyed in the conveying loop, that is, the object carrying plate 5 receives the lens to be assembled on the feeding conveying mechanism 1, the lens is assembled at each assembling mechanism 6 of the assembling conveying mechanism 2, the assembled lens is conveyed into the detecting mechanism 4 by the manipulator for detection, and the empty object carrying plate 5 returns to the feeding conveying mechanism 1 to receive the lens to be assembled, thereby forming circular production and greatly improving the production efficiency.

In the description of the embodiments of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc., indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the several embodiments provided in the present application, it should be understood that the disclosed system, apparatus and method may be implemented in other ways. The above-described embodiments of the apparatus are merely illustrative, and for example, the division of the units is only one logical division, and there may be other divisions when actually implemented, and for example, a plurality of units or components may be combined or integrated into another system, or some features may be omitted, or not executed. In addition, the shown or discussed coupling or direct coupling or communication connection between each other may be through some communication interfaces, indirect coupling or communication connection between devices or units, and may be in an electrical, mechanical or other form.

The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, functional units in the embodiments of the present invention may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (10)

1. A lens assembly cycle production line, comprising:

the device comprises a feeding conveying mechanism, an assembling conveying mechanism, two transferring mechanisms and a detecting mechanism; wherein

The two transfer mechanisms are respectively connected with the end parts of the feeding conveying mechanism and the assembling conveying mechanism to form a conveying loop, a plurality of carrying plates are arranged on the conveying loop, a plurality of assembling mechanisms are arranged on one side of the assembling conveying mechanism, each assembling mechanism is connected with the assembling conveying mechanism, and the detection mechanism is arranged at the tail end of the last stage of assembling mechanism;

each carrying plate circularly rotates on the conveying loop;

when the carrying plate rotates to the feeding conveying mechanism, the carrying plate receives the lens to be assembled;

when the object carrying plate receiving the lens to be assembled is transferred to the assembling and conveying mechanism, the object carrying plate sequentially enters each assembling mechanism;

and the detection mechanism receives and detects the assembled lens.

2. The lens assembly cycle production line of claim 1,

the material loading conveying mechanism comprises: a first conveyor line;

the assembly conveying mechanism comprises: a second conveyor line;

first transfer chain, second transfer chain parallel arrangement, and direction of delivery is reverse to be set up.

3. The lens assembly cycle production line of claim 2,

the transfer mechanism includes: the device comprises a track and a first pushing assembly arranged at one end of the track; wherein

The two rails are respectively connected with the end parts of the first conveying line and the second conveying line to form the conveying loop;

the two first pushing assemblies are respectively arranged on the first conveying line and the second conveying line;

when the first pushing assembly receives the loading plate, the first pushing assembly pushes the loading plate to the other end of the track.

4. The lens assembly cycle production line of claim 3,

the fitting mechanism includes: the assembly table and the second pushing assembly; wherein

The second pushing assembly is arranged on a second conveying line, and the assembling table is connected with the second pushing assembly;

when the second pushing assembly receives the object carrying plate, the second pushing assembly pushes the object carrying plate to the assembling table.

5. The lens assembly cycle production line of claim 4,

a sliding groove is formed in the table top of the assembling table.

6. The lens assembly cycle production line of claim 5,

first propelling movement subassembly, second propelling movement subassembly all include: the device comprises a mounting frame, a pulley block and a driving motor; wherein

The mounting rack is connected with the corresponding conveying line, and the pulley block is arranged on the mounting rack;

the driving motor drives the pulley block to rotate so as to push the carrying plate.

7. The lens assembly cycle production line of claim 6,

the driving motor adopts a servo motor.

8. The lens assembly cycle production line of claim 7,

the rotation direction of the pulley block is vertical to the conveying direction of the corresponding conveying line.

9. The lens assembly cycle production line of claim 8,

and a belt is sleeved on the periphery of the pulley block.

10. The lens assembly cycle production line of claim 1,

the detection mechanism includes: the device comprises a guide plate, a composite plate, a cleaning liquid coating mechanism assembly, a hoisting reset mechanism assembly, a cleaning pool and a second alarm assembly; wherein

The guide plate is positioned between the conveying mechanism and the composite plate, the middle part of the composite plate is provided with a rotating shaft, one end, facing the conveying mechanism, of the composite plate is provided with a lens accommodating groove, a first convex edge is arranged at an inlet of the lens accommodating groove, the hoisting reset mechanism assembly is arranged above the composite plate and is connected with one end, provided with the lens accommodating groove, of the composite plate, the cleaning solution coating mechanism assembly is arranged in the composite plate, the coating end of the cleaning solution coating mechanism assembly extends into the lens accommodating groove, the cleaning pool is positioned below the composite plate, and the second alarm assembly is arranged in the lens accommodating groove;

when the guide plate receives lenses of a first specification, the lenses of the first specification slide into the lens containing groove, the lower surface of the lenses of the first specification is cleaned by the first convex edge, meanwhile, the front end of the lenses of the first specification is guided to stick up and press the coating end of the cleaning liquid coating mechanism assembly so that the cleaning liquid coating mechanism assembly seeps out the cleaning liquid, the end part of the composite plate is stressed to overcome the pulling force of the hoisting reset mechanism assembly and then rotates downwards around the rotating shaft, the lenses of the first specification coated with the cleaning liquid slide out of the lens containing groove and fall into the cleaning pool, and the hoisting reset mechanism assembly drives the composite plate to reset;

when the deflector receives the third specification lens, the third specification lens slides into the lens holding tank, the lower surface of the clean third specification lens of first bead leads the first bead of gliding after the front end perk of third specification lens simultaneously, the second warning subassembly is reported to the police after continuously receiving the pressure of third specification lens.

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