CN114035276A - Automatic assembling mechanism for optical fiber array - Google Patents

Abstract

The invention discloses an automatic assembling mechanism of an optical fiber array, which comprises a substrate conveying mechanism, a substrate clamping mechanism, an optical fiber conveying mechanism and a butting mechanism, wherein a plurality of substrate clamping mechanisms moving on the substrate conveying mechanism are arranged in the substrate conveying mechanism, substrates with upward openings are clamped in the substrate clamping mechanisms, the optical fiber conveying mechanism is arranged on one side of the substrate conveying mechanism and is linked with the substrate conveying mechanism, optical fibers are conveyed side by side through the optical fiber conveying mechanism, the butting mechanism is arranged between the optical fiber conveying mechanism and the substrate conveying mechanism and is butted through the butting mechanism, and a cover plate cover closing mechanism is arranged on one side of the butting mechanism; the base plate and the multi-fiber optical fiber are spliced and assembled in an intelligent processing mode, so that the labor intensity of workers is reduced.

Description

Automatic assembling mechanism for optical fiber array

Technical Field

The invention relates to optical fiber array processing equipment, in particular to an automatic assembling mechanism of an optical fiber array.

Background

Present fiber array mainly processes through the manual work, promptly peel the skin with optic fibre (many optic fibres) tip earlier, then assemble optic fibre and base plate, but in the assembly, because optic fibre is thinner, the staff need be embedded into the draw-in groove of base plate with thinner optic fibre, the operation degree of difficulty is great like this, need the staff to stir the draw-in groove of base plate with optic fibre under the microscope in, then will cover the apron on the base plate, realize the assembly of optic fibre and base plate like this, realize the fixed of optic fibre and base plate like this, but through manual work to optic fibre and base plate, staff's intensity of labour is bigger like this, can't realize fast processing simultaneously, lead to production efficiency to reducing like this, because the fiber array is processed to the manual mode now, can't carry out intelligent processing like this, the efficiency ratio is lower.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides the automatic assembling mechanism of the optical fiber array, which realizes splicing and assembling of the substrate and the multi-fiber optical fibers in an intelligent processing mode, so that the labor intensity of workers is reduced, the assembling efficiency of the optical fibers and the substrate is improved, the processing efficiency of the optical fiber array is improved, and the product quality is ensured by ensuring that the optical fibers are clamped into the clamping grooves of the substrate.

In order to achieve the purpose, the scheme of the invention is as follows: the utility model provides an automatic equipment mechanism of fiber array, including base plate conveying mechanism, base plate clamping machine constructs, fiber conveying mechanism and docking mechanism, wherein be provided with a plurality of base plate clamping machine that move at base plate conveying mechanism in base plate conveying mechanism and construct, the ascending base plate of opening has been blocked in base plate clamping machine constructs, one side at base plate conveying mechanism is provided with fiber conveying mechanism and links with base plate conveying mechanism, carry out side by side the optic fibre through fiber conveying mechanism, be provided with docking mechanism between fiber conveying mechanism and base plate conveying mechanism, dock through docking mechanism, be provided with apron joint cover mechanism on one side of docking mechanism.

Preferably, the substrate clamping mechanism comprises a mounting seat, a clamping groove and a clamping assembly, wherein the mounting seat is provided with the clamping groove for clamping the side surface of the substrate, the top of the mounting seat is provided with the clamping assembly for compressing the substrate in the clamping groove, and the position of the clamping groove corresponds to the position of the optical fiber; the centre gripping subassembly includes two L shaped plates, support tight board, elastic stretching subassembly and centre gripping electromagnetism push rod, wherein set up the breach that supplies the L shaped plate to pass on centre gripping inslot wall, be provided with the centre gripping electromagnetism push rod that drive L shaped plate removed between every L shaped plate and mount pad, be provided with on the inside wall of L shaped plate and support tight board and be provided with elastic stretching subassembly supporting between tight board and L shaped plate inner wall, when the L shaped plate does not ejecting, support the terminal surface parallel and level of tight board and L shaped plate, when the L shaped plate is ejecting to leaning on tightly, the L shaped plate compresses tightly the apron.

Preferably, the substrate conveying mechanism comprises a baffle, clamping blocks and a clamp conveying belt, the baffle for clamping the clamping mechanism is arranged on the two sides of the clamp conveying belt, the height of the baffle is lower than that of the substrate conveying mechanism, the clamping blocks arranged side by side are arranged on the clamp conveying belt, and the two sides of the substrate clamping mechanism are compressed through the clamping blocks, so that alignment of the substrate clamping mechanism is guaranteed.

Preferably, the optical fiber conveying mechanism comprises two compression conveying belts which are arranged up and down and used for compressing the conveying belts and conveying the conveying belts synchronously with the clamp conveying belts, two groove bodies used for tightly holding the optical fibers are arranged on the outer walls of the two compression conveying belts, a limiting component is arranged on one side of the optical fiber conveying mechanism and used for limiting the length of the optical fiber protruding compression conveying belts, a pressing component used for pressing the end portions of the optical fibers downwards is arranged between the optical fiber conveying mechanism and the base plate conveying mechanism, and the end portions of the optical fibers are butted with the base plate through the pressing component.

Preferably, the docking mechanisms are multiple and are positioned above the substrate clamping mechanism, each docking mechanism comprises an alignment roller, a swing frame and a driving assembly, wherein a motor for driving the alignment roller to rotate is arranged at one end of the alignment roller, one end of the swing frame is connected with the alignment roller through a bearing, an installation rod is arranged on one side of the substrate conveying mechanism, the top of the installation rod is hinged with the other end of the swing rod, and the driving assembly for driving the swing rod to rotate is arranged between the installation rod and the swing rod; the outer wall of the alignment roller is provided with a plurality of groove bodies for clamping optical fibers, the head end and the top of each groove body are horn mouths, and the position of each groove body is consistent with the position of the groove body on the substrate and is aligned up and down.

Preferably, the cover plate cover closing mechanism comprises a moving assembly, a cover plate storage assembly, a pushing assembly and a glue brushing assembly, wherein the moving component is positioned at one side of the substrate conveying mechanism far away from the optical fiber conveyor, the moving component and the substrate conveying mechanism are arranged side by side and have the same length as the substrate conveying mechanism, a sliding seat which moves on the moving component is arranged on the moving component, a cover plate storage component is arranged on the sliding seat, the bottom of the cover plate storage component is provided with a pushing component, the outer wall of one side of the bottom of the cover plate storage component close to the substrate conveying mechanism is provided with a notch, a guide channel is arranged between the notch and the clamping groove, the cover plate covers the substrate through the guide channel, a limiting block for limiting the cover plate is arranged on the inner wall, close to the top, of the clamping groove, a glue brushing assembly is arranged in the guide channel, and glue brushing on the bottom of the cover plate is achieved through the glue brushing assembly; a photoelectric alignment assembly is arranged between the movable seat and the plurality of substrate clamping mechanisms, and the cover plate cover closing mechanism is in butt joint with the substrate clamping mechanisms through the photoelectric alignment assembly.

Compared with the prior art, the invention has the advantages that: 1. the mode through intelligent processing realizes that base plate and many fine optic fibre splice the equipment, reduces staff's intensity of labour like this, improves the assembly efficiency of optic fibre and base plate simultaneously, has improved fiber array's machining efficiency like this, and through can guaranteeing in the draw-in groove that the optic fibre card goes into the base plate, guarantee product quality.

Drawings

FIG. 1 is a top view of the present invention.

Fig. 2 is a front view of the present invention.

FIG. 3 is a schematic view of the substrate clamping mechanism of the present invention.

FIG. 4 is a schematic view of a substrate conveying mechanism according to the present invention.

FIG. 5 is a schematic view of an optical fiber delivery mechanism of the present invention.

Fig. 6 is a schematic view of the docking mechanism of the present invention.

The device comprises a base plate conveying mechanism, a retaining plate, a retaining block, a clamping block, a fixture conveying belt, a base plate clamping mechanism, a base plate 2.1, a mounting seat, a clamping groove, a clamping assembly, a 2.5, an L-shaped plate, a 2.6, a pressing plate, a 2.7, an elastic telescopic assembly, a 2.8, a clamping electromagnetic push rod, a 3, an optical fiber conveying mechanism, a 3.1, a pressing conveying belt, a 3.2, a limiting assembly, a 3.3, a pressing assembly, a 4, a butt-joint mechanism, a 4.1, an alignment roller, a 4.2, a swing frame, a 4.3, a mounting rod, a 4.4, a driving assembly, a 5, a cover plate cover closing mechanism, a 5.1, a moving assembly, a 5.2, a cover plate storage assembly, a 5.3, a pushing assembly, a 5.4, a guide channel, a 5.5, a limiting block, a 5.6, a glue brushing assembly, a photoelectric alignment assembly.

Detailed Description

The invention will now be further elucidated with reference to the drawing.

As shown in fig. 1-6, an automatic assembling mechanism for an optical fiber array comprises a substrate conveying mechanism 1, a substrate clamping mechanism 2, an optical fiber conveying mechanism 3 and a docking mechanism 4, wherein the substrate conveying mechanism 1, the substrate clamping mechanism 2, the optical fiber conveying mechanism 3 and the docking mechanism 4 are all fixed on a platform (the platform is a table top) through bolts, a plurality of substrate clamping mechanisms 2 moving on the substrate conveying mechanism 1 are arranged in the substrate conveying mechanism 1, a substrate with an upward opening is clamped in the substrate clamping mechanism 2, so that the substrate moves along with the substrate clamping mechanism 2, the optical fiber conveying mechanism 3 is arranged at the front side of the substrate conveying mechanism 1 and linked with the substrate conveying mechanism 1, the optical fibers are conveyed side by side through the optical fiber conveying mechanism 3, and the positions of the optical fibers correspond to the positions of the substrate (the positions of the optical fibers correspond to the positions of the substrate up and down), the butt joint mechanism 4 is arranged between the optical fiber conveying mechanism 3 and the substrate conveying mechanism 1, butt joint of the optical fibers and the substrate is achieved through the butt joint mechanism 4, butt joint is achieved through the butt joint mechanism 4, the cover plate closing mechanism 5 is arranged on one side of the butt joint mechanism 4, and the cover closing and fixing of the optical fibers and the substrate after butt joint are achieved through the cover plate closing mechanism, so that automatic processing and butt joint of the optical fiber array are achieved.

The substrate clamping mechanism 2 comprises a mounting seat 2.1, a clamping groove 2.2 and a clamping assembly 2.4, wherein the mounting seat 2.1 is provided with the clamping groove 2.2 for clamping the side surface of the substrate, the bottom of the substrate is abutted against the bottom of the clamping groove 2.2, two sides of the substrate are abutted tightly, the top of the mounting seat 2.1 is provided with the clamping assembly 2.4 for pressing the substrate in the clamping groove 2.2, and the position of the clamping groove 2.2 corresponds to the position of the optical fiber; the clamping assembly 2.4 comprises two L-shaped plates 2.5, a resisting plate 2.6, an elastic telescopic assembly 2.7 and a clamping electromagnetic push rod 2.8, wherein a notch for the L-shaped plate 2.5 to pass through is formed in the inner wall of the clamping groove 2.2, a clamping electromagnetic push rod 2.8 for driving the L-shaped plate 2.5 to move is arranged between each L-shaped plate 2.5 and the mounting seat 2.1 (a piston rod of the clamping electromagnetic push rod 2.8 is fixed on the outer side wall of the L-shaped plate 2.5 in a welding manner, a cylinder body of the clamping electromagnetic push rod 2.8 is fixed in the mounting seat 2.1 in a welding manner, the two L-shaped plates 2.5 are drawn together by stretching and retracting of the cylinder), the resisting plate 2.6 is arranged on the inner side wall of the L-shaped plate 2.5, the elastic telescopic assembly 2.7 is a plurality of springs arranged side by side, and two ends of the springs are fixed on the resisting plate 2.6 and the L-shaped plate 2.5 in a welding manner, when L shaped plate 2.5 did not ejecting, support the terminal surface parallel and level of tight board 2.6 and L shaped plate 2.5, when L shaped plate 2.5 was ejecting to lean on tightly, L shaped plate 2.5 compressed tightly the apron, realized the laminating that compresses tightly of apron and base plate like this.

The substrate conveying mechanism 1 comprises a baffle 1.1, a clamping block 1.2 and a clamp conveying belt 1.3, the baffle 1.1 for clamping the clamp mechanism is fixed on platforms on two sides of the clamp conveying belt 1.3 in a bolt fastening mode, the height of the baffle 1.1 is lower than that of the substrate conveying mechanism 1, the clamping blocks 1.2 which are arranged side by side are fixed on the clamp conveying belt 1.3 (namely, a purchased common conveying belt and a roller of the conveying belt are driven by a stepping motor) in a bolt fastening mode, two sides of the substrate clamping mechanism 2 are compressed by the clamping blocks 1.2, conveying of the substrate clamping mechanism 2 is guaranteed, meanwhile, the position of the substrate clamping mechanism 2 on the clamp conveying belt 1.3 is fixed, subsequent alignment of optical fibers and substrates is facilitated (manual alignment operation is not needed), and accordingly butt joint of the substrates and the optical fibers is facilitated.

The optical fiber conveying mechanism 3 comprises two compression conveying belts 3.1 which are arranged up and down, the compression conveying belts 3.1 and the clamp conveying belts 1.3 are synchronously conveyed (the conveying belts are belt pulleys and conveying belts, the belt pulleys are driven by a stepping motor, meanwhile, the stepping motor of the optical fiber conveying mechanism 3 and the stepping motor on the substrate conveying mechanism 1 synchronously work, and linkage is realized by adjusting the rotating speed of the stepping motor), groove bodies for tightly holding optical fibers are arranged on the outer walls of the two compression conveying belts 3.1, a limiting component 3.2 (the limiting component 3.2 is a limiting plate) is fixed on a rear side platform of the optical fiber conveying mechanism 3 in a bolt fastening mode, when the optical fibers are installed in the groove bodies, the end parts of the optical fibers abut against the limiting plate, butt joint is convenient (the optical fibers can extend out of the end parts of the optical fibers to extend out of the substrate, and can not be clamped into the groove bodies of the substrate when the end parts of the optical fibers extend out of the optical fibers to be too short)), the length of the optical fiber protruding and pressing conveyer belt 3.1 is limited by a limiting component 3.2, a pressing component 3.3 for pressing the end part of the optical fiber downwards is arranged between the optical fiber conveying mechanism 3 and the substrate conveying mechanism 1 (the pressing component 3.3 comprises a lifting cylinder, a pressing rod and a limiting groove, a supporting plate is arranged above a platform between the optical fiber conveying mechanism 3 and the substrate conveying mechanism 1, two ends of the supporting plate are welded on the platform through supporting rods, a plurality of lifting cylinders are fixed on the supporting plate in a welding way, the same pressing rod is fixed on piston rods of the plurality of lifting cylinders in a welding way, the lifting of the pressing rod is realized through the lifting cylinder, a plurality of limiting grooves with downward openings are bent on the pressing rod, and the position of each limiting groove corresponds to the position of the substrate clamping mechanism 2), the fiber end is pressed down into abutment with the substrate by pressing down the assembly 3.3 so that the fiber is pressed on top of the substrate and the fiber is in contact with the substrate.

The butt joint mechanisms 4 are multiple, the multiple butt joint mechanisms 4 are positioned above the substrate clamping mechanism 2, the butt joint mechanisms 4 are fixed on the platform through bolts, each butt joint mechanism 4 comprises an alignment roller 4.1, a swing frame 4.2 and a driving component 4.4, wherein one end of each alignment roller 4.1 is fixedly provided with a motor for driving the alignment roller 4.1 to rotate in a welding mode, one end of each swing frame 4.2 is connected with the alignment roller 4.1 through a bearing, a mounting rod 4.3 is fixedly arranged on the platform at the rear side of the substrate conveying mechanism 1 in a bolt fastening mode, the top of the mounting rod 4.3 is hinged with the other end of the swing rod, a driving component 4.4 for driving the swing rod to rotate is arranged between the mounting rod 4.3 and the swing rod, the driving component 4.4 is an air cylinder, the swing of the swing rod is realized through the expansion and contraction of the air cylinder, the two ends of the air cylinder are respectively hinged with the mounting rod 4.3 and the swing rod, when the swing rod swings downwards, the alignment roller 4.1 is pressed above the substrate, and when the oscillating rod oscillates upwards, the alignment roller 4.1 leaves the substrate, so that the substrate clamping mechanism 2 can carry out conveying; offer the multichannel and be used for going into the cell body that the optic fibre was gone into to the card on counterpoint roller 4.1's outer wall, the head end and the top of every cell body are the horn mouth, counterpoint roller 4.1 is convenient for go into the cell body with every card of many fine optic fibre in the time of the pivoted like this (in counterpoint roller 4.1 not pivoted, optic fibre is located horn mouth department, the cell body of counterpoint roller 4.1 simultaneously can only imbed a single fiber, in counterpoint roller 4.1 pivoted, the single fiber enters into the cell body along the horn mouth in, realize the counterpoint of draw-in groove on optic fibre single fiber and the base plate like this, the position of cell body is unanimous and counterpoint from top to bottom on the position of every cell body and the base plate, realize like this that the single fiber card of optic fibre goes into in the cell body.

The cover plate closing mechanism 5 comprises a moving assembly 5.1, a cover plate storage assembly 5.2, a pushing assembly 5.3 and a glue brushing assembly 5.6, wherein the moving assembly 5.1 is positioned at one side (namely the rear side) of the substrate conveying mechanism 1 far away from the optical fiber conveyor, the moving assembly 5.1 and the substrate conveying mechanism 1 are arranged side by side, the moving assembly 5.1 is as long as the substrate conveying mechanism 1, a sliding seat (the sliding seat is a rotor of a linear motor) which moves on the moving assembly 5.1 is arranged on the moving assembly 5.1 (the moving assembly 5.1 is a stator of the linear motor), so that the sliding seat moves on the moving assembly 5.1, the cover plate storage assembly 5.2 (the cover plate storage mechanism is a rectangular placing groove, a plurality of cover plates are stacked up and down in a square groove) is fixed on the sliding seat in a welding manner, the pushing assembly 5.3 (the pushing assembly 5.3 is an air cylinder, and a cylinder body of the air cylinder is fixed on the sliding seat through a bolt), a notch is arranged on the outer wall of one side of the bottom of the cover plate storage assembly and close to the substrate conveying mechanism 1, a guide channel 5.4 is fixed between the notch and the clamping groove 2.2 in a welding mode, the cover plate covers the substrate through the guide channel 5.4 (the cover plate is pushed into the guide channel 5.4 by the pushing assembly 5.3, and the cover plate in the guide channel 5.4 is pushed onto the substrate by the pushing assembly 5.3 to realize fixation), a limiting block 5.5 for limiting the cover plate is fixed on the inner wall of the clamping groove 2.2 close to the top in a welding mode, when the front end of the cover plate is pressed against the limiting block 5.5, the cover plate and the base plate are aligned up and down, a glue brushing assembly 5.6 is arranged in the guide channel 5.4 (the glue brushing assembly 5.6 is a rubber tube, the rubber tube is positioned below the tail part of the guide channel 5.4 (glue is sprayed out of the rubber tube), glue brushing at the bottom of the cover plate is realized through the glue brushing assembly 5.6), and glue brushing at the bottom of the cover plate is realized through the glue brushing assembly 5.6; be provided with photoelectricity counterpoint subassembly 6 between removal seat and a plurality of base plate clamping machine structure 2 (photoelectricity counterpoint subassembly 6 includes laser emission head and receiver, the embedding has the infrared emission head on every mount pad 2.1's trailing flank, be fixed with receiver and linear electric motor through the mode of embedding on removing the seat and be connected, when laser emission head and receiver carry out the butt joint, linear electric motor stop work, promote the subassembly simultaneously and will lap to base plate propelling movement and cover on the base plate, L shaped plate 2.5 extends and will lap on the base plate to centre gripping groove 2.2 in simultaneously, realize the butt joint of apron closing cover mechanism 5 and base plate clamping machine structure 2 through photoelectricity counterpoint subassembly 6, base plate clamping machine structure 2 after finishing processing takes away through the staff, only need the staff material loading and unloading like this.

Claims (6)

1. The utility model provides an automatic equipment mechanism of fiber array, including base plate conveying mechanism, base plate clamping machine constructs, fiber conveying mechanism and docking mechanism, a serial communication port, wherein be provided with a plurality of base plate clamping machine that move at base plate conveying mechanism in the base plate conveying mechanism, the ascending base plate of opening has been blocked in base plate clamping machine constructs, be provided with fiber conveying mechanism and carry out the linkage with base plate conveying mechanism in one side of base plate conveying mechanism, carry out the side by side transport to optic fibre through fiber conveying mechanism, be provided with docking mechanism between fiber conveying mechanism and base plate conveying mechanism, dock through docking mechanism, be provided with apron joint cover mechanism on one side of docking mechanism.

2. The automatic assembling mechanism for an optical fiber array according to claim 1, wherein the substrate clamping mechanism comprises a mounting seat, a clamping groove, and a clamping assembly, wherein the mounting seat is provided with the clamping groove for clamping the side surface of the substrate, the top of the mounting seat is provided with the clamping assembly for compressing the substrate in the clamping groove, and the position of the clamping groove corresponds to the position of the optical fiber; the centre gripping subassembly includes two L shaped plates, support tight board, elastic stretching subassembly and centre gripping electromagnetism push rod, wherein set up the breach that supplies the L shaped plate to pass on centre gripping inslot wall, be provided with the centre gripping electromagnetism push rod that drive L shaped plate removed between every L shaped plate and mount pad, be provided with on the inside wall of L shaped plate and support tight board and be provided with elastic stretching subassembly supporting between tight board and L shaped plate inner wall, when the L shaped plate does not ejecting, support the terminal surface parallel and level of tight board and L shaped plate, when the L shaped plate is ejecting to leaning on tightly, the L shaped plate compresses tightly the apron.

3. The automatic assembling mechanism for the optical fiber array according to claim 2, wherein the substrate conveying mechanism comprises a baffle, a clamping block and a clamp conveying belt, the baffle for clamping the clamping mechanism is arranged on two sides of the clamp conveying belt, the height of the baffle is lower than that of the substrate conveying mechanism, the clamping block is arranged on the clamp conveying belt side by side, and the two sides of the substrate clamping mechanism are pressed tightly through the clamping block, so that alignment of the substrate clamping mechanism is ensured.

4. The automatic assembling mechanism for the optical fiber array according to claim 3, wherein the optical fiber conveying mechanism comprises two pressing conveying belts which are arranged up and down and are conveyed synchronously with the clamp conveying belt, groove bodies for alarming the optical fibers are arranged on the outer walls of the two pressing conveying belts, a limiting component is arranged on one side of the optical fiber conveying mechanism, the length of the protruding pressing conveying belt of the optical fibers is limited by the limiting component, a pressing component for pressing the end portions of the optical fibers downwards is arranged between the optical fiber conveying mechanism and the substrate conveying mechanism, and the butt joint of the end portions of the optical fibers and the substrate is realized by pressing the pressing component downwards.

5. The automatic assembling mechanism of an optical fiber array according to claim 4, wherein the docking mechanism is a plurality of docking mechanisms, the plurality of docking mechanisms are located above the substrate clamping mechanism, the docking mechanism comprises an alignment roller, a swing frame and a driving assembly, wherein a motor for driving the alignment roller to rotate is arranged at one end of the alignment roller, one end of the swing frame is connected with the alignment roller through a bearing, a mounting rod is arranged at one side of the substrate conveying mechanism, the top of the mounting rod is hinged with the other end of the swing rod, and the driving assembly for driving the swing rod to rotate is arranged between the mounting rod and the swing rod; the outer wall of the alignment roller is provided with a plurality of groove bodies for clamping optical fibers, the head end and the top of each groove body are horn mouths, and the position of each groove body is consistent with the position of the groove body on the substrate and is aligned up and down.

6. The automatic assembling mechanism of an optical fiber array according to claim 5, wherein the cover plate closing mechanism comprises a moving assembly, a cover plate storage assembly, an ejector assembly and a glue brushing assembly, wherein the moving assembly is located at a side of the substrate conveying mechanism away from the optical fiber conveyor, the moving assembly and the substrate conveying mechanism are arranged side by side, the moving assembly is as long as the substrate conveying mechanism, a sliding seat for moving on the moving assembly is arranged on the moving assembly, the cover plate storage assembly is arranged on the sliding seat, the ejector assembly is arranged at the bottom of the cover plate storage assembly, a notch is formed on an outer wall of a side of the bottom of the cover plate storage assembly close to the substrate conveying mechanism, a guide channel is arranged between the notch and the clamping groove, the cover plate covers the substrate through the guide channel, and a limiting block for limiting the cover plate is arranged on an inner wall of the clamping groove close to the top, a glue brushing assembly is arranged in the guide channel, and glue brushing on the bottom of the cover plate is realized through the glue brushing assembly; a photoelectric alignment assembly is arranged between the movable seat and the plurality of substrate clamping mechanisms, and the cover plate cover closing mechanism is in butt joint with the substrate clamping mechanisms through the photoelectric alignment assembly.

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