CN114515963A

CN114515963A - Full-automatic optical module multi-process assembling equipment

Info

Publication number: CN114515963A
Application number: CN202210159418.1A
Authority: CN
Inventors: 黎裕敏; 黄祖钦
Original assignee: Huizhou Yuanbao Metal Casting Co ltd
Current assignee: Huizhou Yuanbao Metal Casting Co ltd
Priority date: 2022-02-21
Filing date: 2022-02-21
Publication date: 2022-05-20
Anticipated expiration: 2042-02-21
Also published as: CN114515963B

Abstract

The invention discloses full-automatic optical module multi-process assembling equipment, and relates to the field of automatic assembling of optical modules. This full-automatic optical module multi-process equipment, the mid-mounting of processing platform has the drive cingulum, and the surface of drive cingulum is equipped with the processing support plate, and automatic hydraulic push rod fixed mounting just is located the both sides of drive cingulum at the upper surface of processing platform, and automatic hydraulic push rod's output fixed mounting has the triangle ejector pad, and the rectangular channel with triangle ejector pad looks adaptation is all seted up to the bottom both sides of processing support plate, and the bottom fixedly connected with drive rack of processing support plate, drive rack meshes with the drive cingulum mutually. The full-automatic optical module multi-process assembling equipment can conveniently realize positioning and fixing of workpieces during circulating operation on a production line, and meanwhile, influence on the machining process of other workpieces is avoided, and machining efficiency is effectively improved.

Description

Full-automatic optical module multi-process assembling equipment

Technical Field

The invention relates to the technical field of automatic assembly of optical modules, in particular to full-automatic multi-process assembly equipment for optical modules.

Background

The optical module comprises an optical receiving module, an optical transmitting-receiving integrated module, an optical forwarding module and the like, is an optoelectronic device for performing photoelectric and electro-optical conversion, a transmitting end of the optical module converts an electric signal into an optical signal, a receiving end of the optical module converts the optical signal into the electric signal, and the transmitting-receiving integrated module mainly has the functions of realizing photoelectric conversion, including optical power control, modulation transmission, signal detection, IV conversion, amplitude limiting amplification judgment regeneration functions, anti-counterfeiting information inquiry and the like.

However, when the optical module is assembled, a plurality of steps are required, and since the components of the optical module are very fine, thus, essentially every assembly step is automated using mechanical equipment, but between the various processing steps, manual transfer is required, most of the prior semi-automatic production still has low actual production efficiency, and the problems of processing leakage and processing dislocation are caused by inaccurate positioning and untimely fixing in many times, so that the qualification rate of products is low, and after mechanical equipment used by a plurality of processing steps are combined together, when one part fails, the whole optical module can not be used continuously, and the subsequent processing production is influenced because the stop processing is needed, so that the full-automatic optical module multi-process assembling equipment needs to be provided to solve the problems.

Disclosure of Invention

Aiming at the defects of the prior art, the invention discloses a full-automatic optical module multi-process assembly device, which aims to solve the problems in the background art.

In order to achieve the purpose, the invention is realized by the following technical scheme: a full-automatic optical module multi-process assembly equipment comprises:

The processing platform comprises a processing platform, wherein a feeding transmission belt and a discharging transmission belt are respectively and fixedly mounted at two ends of one side of the processing platform, an accessory transmission belt is fixedly mounted in the middle of the other side of the processing platform, a driving toothed belt is mounted in the middle of the processing platform, a processing support plate is arranged on the outer surface of the driving toothed belt, a carrier is arranged at the top of the processing platform, a feeding machine, an assembling machine, a welding machine, a screw twisting machine and a discharging machine are sequentially arranged on the lower surface of the carrier, a fixing mechanism is arranged at the top of the carrier, and a plurality of groups of fixing mechanisms are respectively and fixedly mounted with the feeding machine, the assembling machine, the welding machine, the screw twisting machine and the discharging machine;

the automatic hydraulic push rod, automatic hydraulic push rod fixed mounting just is located the both sides of drive cingulum at the upper surface of processing platform, automatic hydraulic push rod's output fixed mounting has the triangle ejector pad, the rectangular channel with triangle ejector pad looks adaptation is all seted up to the bottom both sides of processing support plate, the bottom fixedly connected with driving rack of processing support plate, driving rack meshes with the drive cingulum mutually.

Preferably, the middle part of processing platform is equipped with fixed guide, the inside all rotation in both ends of processing platform is connected with changes the roller, the surface at two sets of roller that change is cup jointed in the activity of drive cingulum, the bottom of processing support plate is equipped with coupling assembling, coupling assembling's bottom swing joint is in fixed guide's inside.

Preferably, a driving motor is fixedly mounted on one side of the processing table, an output end of the driving motor is fixedly mounted with a group of rotating rollers, a cross-shaped fixing frame is fixedly connected inside the fixed guide rail, and two ends of the cross-shaped fixing frame are fixedly connected with the processing table.

Preferably, the connecting assembly comprises a connecting cylinder, a connecting strip, a T-shaped rod and a connecting spring, the connecting strip is fixedly connected to the top end of the connecting cylinder, the T-shaped rod is movably inserted into the connecting strip, the connecting spring is movably sleeved on the outer surface of the bottom end of the T-shaped rod, and the top end of the connecting spring is abutted to the inner top of the connecting strip.

Preferably, the top end of the connecting strip is movably inserted into the bottom of the processing carrier plate, the top end of the T-shaped rod is fixedly connected into the processing carrier plate, a limiting groove is formed in the outer surface of the fixed guide rail, and the connecting cylinder is connected into the limiting groove in a sliding mode.

Preferably, the fixing mechanism comprises a fixing seat, an insertion rod, a connecting rack, a rotating head, a rotating shaft and a transmission gear, the connecting rack is movably inserted into the two ends of the fixing seat, the insertion rod is fixedly connected to the outer end of the connecting rack, the rotating shaft is rotatably connected to the upper surface of the fixing seat, the rotating head and the transmission gear are respectively and fixedly connected to the upper end and the lower end of the rotating shaft, and the transmission gear is meshed with the connecting rack.

Preferably, the upper surfaces of the feeding machine, the assembling machine, the welding machine, the screw twisting machine and the blanking machine are fixedly connected through a fixing plate, the top end of the fixing plate is fixedly connected with a clamping plate, the clamping plate is movably inserted into the top of the carrier frame, and the inserted rod is movably inserted into the clamping plate.

Preferably, the outer end fixedly connected with connection piece of connecting rack, inserted bar fixed connection is at the surface of connection piece, the opposite side fixedly connected with locating lever of connection piece, the locating lever activity is pegged graft in the inside of fixing base, the side fixedly connected with gag lever post of connecting rack, reset spring has been cup jointed in the surface activity of gag lever post, the other end activity of gag lever post is pegged graft inside the connecting rack of relative one side.

The invention discloses a full-automatic optical module multi-process assembly device, which has the following beneficial effects:

1. the full-automatic multi-process assembling equipment for the optical module is characterized in that a feeding machine, an assembling machine, a welding machine, a screw twisting machine and a discharging machine are arranged at the top of a processing table, meanwhile, an automatic hydraulic push rod is arranged below each group of processing parts, when the processing support plate moves to the position of the automatic hydraulic push rod, a distance sensor in the automatic hydraulic push rod senses the position of the processing carrier plate, the triangular push block is controlled to automatically move towards the middle part at the moment, the triangular push block is inserted into the rectangular groove at the moment to lift the processing carrier plate upwards, so that the transmission rack at the bottom of the processing carrier plate is separated from the driving toothed belt, the driving toothed belt continues to move, but this processing support plate can't continue to remove along with the drive cingulum, can realize the location of work piece when convenient circulation operation on the assembly line fixed, avoids influencing other work piece course of working simultaneously, effectively improves machining efficiency.

2. This full-automatic optical module multi-process equipment, rotate the head through anticlockwise rotation, make drive gear anticlockwise rotation, make two sets of connecting rack remove to the middle part, the inserted bar shifts out from the inside of cardboard this moment, reset spring is compressed simultaneously, hold this processing part and take off from the lower surface of carrier frame downwards slow movement this moment, then change reserve processing part, then loosen and rotate the head, this moment under reset spring's effect, the inserted bar inserts the inside of cardboard and carries out the joint fixed, make things convenient for the processing part of quick replacement damage, reduce the influence to processing production.

3. According to the full-automatic optical module multi-process assembly equipment, the connecting assembly is arranged at the bottom of the processing carrier plate, when the equipment is used, the processing carrier plate moves forwards and finally returns from the lower part of the processing table, and moves downwards through the limiting groove, at the moment, the processing carrier plate is always kept to be tightly attached to the outer surface of the fixed guide rail under the action of the connecting spring, so that the transmission rack and the driving toothed belt are always in a meshed state, and the driving toothed belt can drive the processing carrier plate to return to the front end of the processing table from the lower part for continuous material loading processing.

Drawings

FIG. 1 is a schematic view of the overall front structure of the present invention;

FIG. 2 is a schematic view of the overall backside structure of the present invention;

FIG. 3 is a sectional view of the outer surface structure of the fixing plate according to the present invention;

FIG. 4 is an enlarged view of the portion A of FIG. 3 according to the present invention;

FIG. 5 is an exploded view of the internal structure of the processing station of the present invention;

FIG. 6 is a schematic view of a lower surface structure of a carrier plate according to the present invention;

fig. 7 is a schematic view of a connecting assembly according to the present invention.

In the figure: 1. a processing table; 2. a feeding conveying belt; 3. a blanking conveying belt; 4. a carrier; 5. a feeding machine; 6. an assembly machine; 7. welding machine; 8. screwing machine; 9. a blanking machine; 10. a accessory conveyor belt; 11. processing a carrier plate; 12. an automatic hydraulic push rod; 13. a drive motor; 14. a fixing mechanism; 141. a fixed seat; 142. inserting a rod; 143. connecting the racks; 144. rotating the head; 145. a rotating shaft; 146. a transmission gear; 15. a fixing plate; 16. clamping a plate; 17. connecting sheets; 18. positioning a rod; 19. a limiting rod; 20. a return spring; 21. rotating the roller; 22. a drive toothed belt; 23. fixing the guide rail; 24. a cross-shaped fixing frame; 25. a limiting groove; 26. a connecting assembly; 261. a connecting cylinder; 262. a connecting strip; 263. a T-shaped rod; 264. a connecting spring; 27. a rectangular groove; 28. a triangular push block; 29. a transmission rack.

Detailed Description

The embodiment of the invention discloses a full-automatic optical module multi-process assembling device, which comprises a processing table 1, wherein two ends of one side of the processing table 1 are respectively and fixedly provided with a feeding transmission belt 2 and a discharging transmission belt 3, the middle part of the other side of the processing table 1 is fixedly provided with an accessory transmission belt 10, the middle part of the processing table 1 is provided with a driving toothed belt 22, the outer surface of the driving toothed belt 22 is provided with a processing support plate 11, the top of the processing table 1 is provided with a carrier frame 4, the lower surface of the carrier frame 4 is sequentially provided with a feeding machine 5, an assembling machine 6, a welding machine 7, a screw twisting machine 8 and a discharging machine 9, the top of the carrier frame 4 is provided with a fixing mechanism 14, and a plurality of groups of fixing mechanisms 14 are respectively and fixedly arranged with the feeding machine 5, the assembling machine 6, the welding machine 7, the screw twisting machine 8 and the discharging machine 9;

meanwhile, the device further comprises an automatic hydraulic push rod 12, the automatic hydraulic push rod 12 is fixedly installed on the upper surface of the processing table 1 and located on two sides of the driving toothed belt 22, a triangular push block 28 is fixedly installed at an output end of the automatic hydraulic push rod 12, rectangular grooves 27 matched with the triangular push block 28 are formed in two sides of the bottom of the processing carrier plate 11, a transmission rack 29 is fixedly connected to the bottom of the processing carrier plate 11, the transmission rack 29 is meshed with the driving toothed belt 22, a distance sensor is arranged inside the automatic hydraulic push rod 12, and the position of the processing carrier plate 11 is sensed through the distance sensor to control the stretching of the automatic hydraulic push rod 12, so that the triangular push block 28 limits and fixes the processing carrier plate 11.

Referring to fig. 1, 2 and 5, a fixed guide rail 23 is arranged in the middle of a processing table 1, rotating rollers 21 are rotatably connected inside two ends of the processing table 1, a driving toothed belt 22 is movably sleeved on the outer surfaces of the two sets of rotating rollers 21, a connecting assembly 26 is arranged at the bottom of a processing support plate 11, the bottom end of the connecting assembly 26 is movably connected inside the fixed guide rail 23, a driving motor 13 is fixedly installed on one side of the processing table 1, the output end of the driving motor 13 is fixedly installed on one set of rotating rollers 21, a cross fixing frame 24 is fixedly connected inside the fixed guide rail 23, two ends of the cross fixing frame 24 are fixedly connected with the processing table 1, and by starting the driving motor 13, the driving motor 13 drives the driving toothed belt 22 to circularly rotate through the rotating rollers 21, and the processing support plate 11 circularly moves along the fixed guide rail 23.

Referring to fig. 6-7, the connecting assembly 26 includes a connecting cylinder 261, a connecting bar 262, a T-shaped rod 263 and a connecting spring 264, the connecting bar 262 is fixedly connected to the top end of the connecting cylinder 261, the T-shaped rod 263 is movably inserted into the connecting bar 262, the connecting spring 264 is movably sleeved on the outer surface of the bottom end of the T-shaped rod 263, the top end of the connecting spring 264 abuts against the inner top of the connecting bar 262, the top end of the connecting bar 262 is movably inserted into the bottom of the processing carrier plate 11, the top end of the T-shaped rod 263 is fixedly connected into the processing carrier plate 11, a limiting groove 25 is formed on the outer surface of the fixed guide rail 23, the connecting cylinder 261 is slidably connected into the limiting groove 25, the cross section of the limiting groove 25 is in an inverted T shape, the connecting cylinder 261 can slide and rotate in the limiting groove 25, the processing carrier plate 11 can conveniently move at two ends of the fixed guide rail 23, and under the action of the connecting spring 264, the processing carrier 11 is always kept tightly attached to the outer surface of the fixed guide rail 23, so that the transmission rack 29 and the driving toothed belt 22 are always in a meshed state, and the driving toothed belt 22 can drive the processing carrier 11 to move.

Referring to fig. 1-4, the fixing mechanism 14 includes a fixed base 141, a plunger 142, a connecting rack 143, a rotating head 144, a rotating shaft 145 and a transmission gear 146, the connecting rack 143 is movably inserted inside two ends of the fixed base 141, the plunger 142 is fixedly connected to an outer end of the connecting rack 143, the rotating shaft 145 is rotatably connected to an upper surface of the fixed base 141, the rotating head 144 and the transmission gear 146 are respectively fixedly connected to upper and lower ends of the rotating shaft 145, the transmission gear 146 is engaged with the connecting rack 143, upper surfaces of the feeder 5, the assembler 6, the welder 7, the screwing machine 8 and the unloader 9 are all fixedly connected to a fixing plate 15, a card plate 16 is fixedly connected to a top end of the fixing plate 15, the card plate 16 is movably inserted on a top of the carrier 4, the plunger 142 is movably inserted inside the card plate 16, and the transmission gear 146 is rotated counterclockwise by rotating the rotating head 144 counterclockwise, so that the two sets of the connecting rack 143 drive the plunger 142 to move out of the card plate 16, the processing part is convenient to be taken down from the lower surface of the carrier 4 for replacement.

Referring to fig. 1-4, the outer end of the connecting rack 143 is fixedly connected with a connecting piece 17, the inserted link 142 is fixedly connected to the outer surface of the connecting piece 17, the other side of the connecting piece 17 is fixedly connected with a positioning rod 18, the positioning rod 18 is movably inserted into the fixing seat 141, the side surface of the connecting rack 143 is fixedly connected with a limiting rod 19, the outer surface of the limiting rod 19 is movably sleeved with a return spring 20, the other end of the limiting rod 19 is movably inserted into the connecting rack 143 on the opposite side, and the return spring 20 can keep the inserted link 142 inserted into the clamping plate 16 all the time.

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions of the embodiments of the present invention will be clearly and completely described below by way of examples with reference to the accompanying drawings in the present invention.

The first embodiment,

As shown in fig. 1-7, a full-automatic optical module multi-process assembling device comprises a processing table 1, wherein a feeding transmission belt 2 and a discharging transmission belt 3 are respectively and fixedly installed at two ends of one side of the processing table 1, an accessory transmission belt 10 is fixedly installed at the middle of the other side of the processing table 1, a driving toothed belt 22 is installed at the middle of the processing table 1, a processing carrier plate 11 is arranged on the outer surface of the driving toothed belt 22, a carrier 4 is arranged at the top of the processing table 1, a feeding machine 5, an assembling machine 6, a welding machine 7, a screw screwing machine 8 and a discharging machine 9 are sequentially arranged on the lower surface of the carrier 4, a fixing mechanism 14 is arranged at the top of the carrier 4, and a plurality of groups of fixing mechanisms 14 are respectively and fixedly installed with the feeding machine 5, the assembling machine 6, the welding machine 7, the screw screwing machine 8 and the discharging machine 9;

the automatic hydraulic push rod 12, the automatic hydraulic push rod 12 is fixedly installed on the upper surface of the processing table 1 and located on two sides of the driving toothed belt 22, the output end of the automatic hydraulic push rod 12 is fixedly installed with a triangular push block 28, two sides of the bottom of the processing carrier plate 11 are both provided with rectangular grooves 27 matched with the triangular push block 28, the bottom of the processing carrier plate 11 is fixedly connected with a driving rack 29, the driving rack 29 is meshed with the driving toothed belt 22, the middle of the processing table 1 is provided with a fixed guide rail 23, the inner parts of two ends of the processing table 1 are both rotatably connected with the rotating rollers 21, the driving toothed belt 22 is movably sleeved on the outer surfaces of the two groups of rotating rollers 21, the bottom of the processing carrier plate 11 is provided with a connecting assembly 26, the bottom end of the connecting assembly 26 is movably connected inside the fixed guide rail 23, one side of the processing table 1 is fixedly installed with a driving motor 13, the output end of the driving motor 13 is fixedly installed with one group of the rotating rollers 21, the inner part of the fixed guide rail 23 is fixedly connected with a cross-shaped fixing frame 24, the two ends of the cross-shaped fixing frame 24 are fixedly connected with the processing table 1, the connecting assembly 26 comprises a connecting cylinder 261, a connecting strip 262, a T-shaped rod 263 and a connecting spring 264, the connecting strip 262 is fixedly connected to the top end of the connecting cylinder 261, the T-shaped rod 263 is movably inserted into the connecting strip 262, the connecting spring 264 is movably sleeved on the outer surface of the bottom end of the T-shaped rod 263, the top end of the connecting spring 264 abuts against the inner top of the connecting strip 262, the top end of the connecting strip 262 is movably inserted into the bottom of the processing carrier plate 11, the top end of the T-shaped rod 263 is fixedly connected into the processing carrier plate 11, a limiting groove 25 is formed in the outer surface of the fixed guide rail 23, and the connecting cylinder 261 is slidably connected into the limiting groove 25;

When the device is used, a workpiece body to be processed is placed on the feeding conveying belt 2 and conveyed to one side of the front end of the processing table 1 through the feeding conveying belt 2, at the moment, the processing carrier plate 11 is always connected with the fixed guide rail 23 through the connecting assembly 26 at the bottom of the processing carrier plate, and is kept in a clamping state with the driving toothed belt 22 through the transmission rack 29, at the moment, the driving motor 13 is started, the driving motor 13 drives the driving toothed belt 22 to circularly rotate through the rotating roller 21, so that the processing carrier plate 11 circularly moves along the fixed guide rail 23, when the processing carrier plate 11 moves to the position of the automatic hydraulic push rod 12, the distance sensor in the automatic hydraulic push rod 12 senses the position of the processing carrier plate 11, at the moment, the triangular push block 28 is controlled to automatically move towards the middle part, at the moment, the triangular push block 28 is inserted into the rectangular groove 27 to lift the processing carrier plate 11 upwards, the transmission rack 29 at the bottom of the processing carrier 11 is separated from the driving toothed belt 22, and in the process, as the processing carrier 11 moves upward, the T-shaped rod 263 is driven to move upward, so that the connecting spring 264 is compressed, and at this time, the driving toothed belt 22 continues to move, but the processing carrier 11 cannot continue to move along with the driving toothed belt 22;

At this time, a set of workpieces on the feeding conveyor belt 2 is clamped and moved to the processing carrier plate 11 for limiting through the feeding machine 5, then the automatic hydraulic push rod 12 controls the two sets of triangular push blocks 28 to move out of the rectangular groove 27, at this time, under the action of the elastic force of the connecting spring 264 and the self gravity of the processing carrier plate 11, the processing carrier plate 11 falls back downwards, so that the driving rack 29 is meshed with the driving toothed belt 22 again, at this time, the driving toothed belt 22 continues to drive the processing carrier plate 11 to move forwards to enter the next stage of processing position, the steps are repeated, the processing carrier plate 11 is jacked up through the other set of automatic hydraulic push rod 12 for limiting, the optical module is assembled, welded and fixed through the assembling machine 6, the welding machine 7 and the screwing machine 8 in sequence, and finally, the assembled workpieces are clamped and moved to the discharging conveyor belt 3 through the discharging machine 9 for discharging, the integrated full-automatic processing flow of the whole material is completed;

meanwhile, the processing carrier plate 11 continues to move forward, and moves downward through the arc-shaped structure at the end of the limiting groove 25, so that the material is returned from the bottom of the processing table 1, at this time, under the action of the connecting spring 264, the processing carrier plate 11 always keeps close to the outer surface of the fixed guide rail 23, so that the transmission rack 29 and the driving toothed belt 22 are always in a meshed state, and the driving toothed belt 22 can drive the processing carrier plate 11 to return to the front end of the processing table 1 from below for continuous material-carrying processing.

Example II,

As shown in fig. 1-7, a full-automatic optical module multi-process assembly device comprises a processing table 1, wherein a feeding conveyor belt 2 and a discharging conveyor belt 3 are respectively and fixedly installed at two ends of one side of the processing table 1, an accessory conveyor belt 10 is fixedly installed at the middle of the other side of the processing table 1, a driving toothed belt 22 is installed at the middle of the processing table 1, a processing carrier plate 11 is arranged on the outer surface of the driving toothed belt 22, a carrier frame 4 is arranged at the top of the processing table 1, a feeding machine 5, an assembling machine 6, a welding machine 7, a screw twisting machine 8 and a discharging machine 9 are sequentially arranged on the lower surface of the carrier frame 4, a fixing mechanism 14 is arranged at the top of the carrier frame 4, and a plurality of groups of fixing mechanisms 14 are respectively and fixedly installed with the feeding machine 5, the assembling machine 6, the welding machine 7, the screw twisting machine 8 and the discharging machine 9;

the fixing mechanism 14 comprises a fixed seat 141, an inserted link 142, a connecting rack 143, a rotating head 144, a rotating shaft 145 and a transmission gear 146, the connecting rack 143 is movably inserted inside two ends of the fixed seat 141, the inserted link 142 is fixedly connected to the outer end of the connecting rack 143, the rotating shaft 145 is rotatably connected to the upper surface of the fixed seat 141, the rotating head 144 and the transmission gear 146 are respectively and fixedly connected to the upper and lower ends of the rotating shaft 145, the transmission gear 146 is engaged with the connecting rack 143, the upper surfaces of the feeding machine 5, the assembling machine 6, the welding machine 7, the screwing machine 8 and the blanking machine 9 are all fixedly connected with a fixing plate 15, the top end of the fixing plate 15 is fixedly connected with a clamping plate 16, the clamping plate 16 is movably inserted at the top of the carrier frame 4, the inserted link 142 is movably inserted inside the clamping plate 16, the outer end of the connecting rack connecting piece 143 is fixedly connected with a connecting piece 17, the inserted link 142 is fixedly connected to the outer surface of the positioning rod 17, the other side of the positioning rod 17 is fixedly connected with a positioning rod 18, the positioning rod 18 is movably inserted in the fixing seat 141, the side surface of the connecting rack 143 is fixedly connected with a limiting rod 19, the outer surface of the limiting rod 19 is movably sleeved with a return spring 20, and the other end of the limiting rod 19 is movably inserted in the connecting rack 143 on the opposite side;

In the using process of the device, when a part of a certain processing link has a fault, the rotating head 144 at the top of the processing part is rotated anticlockwise, so that the rotating head 144 drives the transmission gear 146 to rotate anticlockwise through the rotating shaft 145, two groups of connecting racks 143 move towards the middle part, at the moment, the connecting racks 143 drive the inserting rods 142 to move out of the clamping plates 16 through the connecting pieces 17, the limiting rods 19 move towards the inside of the connecting racks 143, at the moment, the return springs 20 are compressed, at the moment, the processing part is supported and moves downwards slowly to be taken down from the lower surface of the carrier 4, then, the spare processing part is replaced, the clamping plates 16 at the top of the spare processing part are inserted into the carrier 4 again, then, the rotating head 144 is loosened, at the moment, under the action of the return springs 20, the inserting rods 142 are inserted into the clamping plates 16 to be clamped and fixed, and the damaged processing part can be replaced quickly, the influence on processing production is reduced.

The foregoing shows and describes the general principles and features of the present invention, together with the advantages thereof. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. A full-automatic optical module multi-process assembly equipment is characterized by comprising:

a processing table (1), wherein a feeding conveying belt (2) and a discharging conveying belt (3) are respectively and fixedly arranged at two ends of one side of the processing table (1), the middle part of the other side of the processing table (1) is fixedly provided with an accessory transmission belt (10), a driving toothed belt (22) is arranged in the middle of the processing table (1), a processing carrier plate (11) is arranged on the outer surface of the driving toothed belt (22), a carrier (4) is arranged at the top of the processing table (1), a feeding machine (5), an assembling machine (6), a welding machine (7), a screw twisting machine (8) and a blanking machine (9) are sequentially arranged on the lower surface of the carrier (4), the top of the carrier (4) is provided with a fixing mechanism (14), and a plurality of groups of fixing mechanisms (14) are respectively fixedly installed with the feeding machine (5), the assembling machine (6), the welding machine (7), the screw twisting machine (8) and the blanking machine (9);

automatic hydraulic rod (12), automatic hydraulic rod (12) fixed mounting just is located the both sides of drive cingulum (22) at the upper surface of processing platform (1), the output fixed mounting of automatic hydraulic rod (12) has triangle ejector pad (28), rectangular channel (27) with triangle ejector pad (28) looks adaptation are all seted up to the bottom both sides of processing support plate (11), the bottom fixedly connected with driving rack (29) of processing support plate (11), driving rack (29) mesh with drive cingulum (22).

2. The fully automatic optical module multi-process assembly equipment of claim 1, wherein: the middle part of processing platform (1) is equipped with fixed guide rail (23), the inside both ends of processing platform (1) are all rotated and are connected with commentaries on classics roller (21), drive cingulum (22) activity is cup jointed at two sets of surfaces of changeing roller (21), the bottom of processing support plate (11) is equipped with coupling assembling (26), the bottom swing joint of coupling assembling (26) is in the inside of fixed guide rail (23).

3. The fully automatic optical module multi-process assembly equipment according to claim 2, wherein: processing platform (1)'s one side fixed mounting has driving motor (13), driving motor's (13) output and a set of commentaries on classics roller (21) fixed mounting, the inside fixedly connected with cross mount (24) of fixed guide (23), the both ends and the processing platform (1) fixed connection of cross mount (24).

4. The fully automatic optical module multi-process assembly equipment according to claim 2, wherein: the connecting assembly (26) comprises a connecting cylinder (261), a connecting strip (262), a T-shaped rod (263) and a connecting spring (264), the connecting strip (262) is fixedly connected to the top end of the connecting cylinder (261), the T-shaped rod (263) is movably inserted into the connecting strip (262), the connecting spring (264) is movably sleeved on the outer surface of the bottom end of the T-shaped rod (263), and the top end of the connecting spring (264) is abutted to the inner top of the connecting strip (262).

5. The fully automatic optical module multi-process assembly equipment of claim 4, wherein: the top end of the connecting strip (262) is movably inserted at the bottom of the processing carrier plate (11), the top end of the T-shaped rod (263) is fixedly connected inside the processing carrier plate (11), the outer surface of the fixed guide rail (23) is provided with a limiting groove (25), and the connecting cylinder (261) is connected inside the limiting groove (25) in a sliding manner.

6. The fully automatic optical module multi-process assembly equipment of claim 1, wherein: the fixing mechanism (14) comprises a fixing seat (141), an inserting rod (142), a connecting rack (143), a rotating head (144), a rotating shaft (145) and a transmission gear (146), the connecting rack (143) is movably inserted into the two ends of the fixing seat (141), the inserting rod (142) is fixedly connected to the outer end of the connecting rack (143), the rotating shaft (145) is rotatably connected to the upper surface of the fixing seat (141), the rotating head (144) and the transmission gear (146) are respectively and fixedly connected to the upper end and the lower end of the rotating shaft (145), and the transmission gear (146) is meshed with the connecting rack (143).

7. The fully automatic optical module multi-process assembly equipment of claim 6, wherein: the upper surfaces of the feeding machine (5), the assembling machine (6), the welding machine (7), the screw twisting machine (8) and the blanking machine (9) are fixedly connected through a fixing plate (15), the top end of the fixing plate (15) is fixedly connected with a clamping plate (16), the clamping plate (16) is movably inserted into the top of the carrier frame (4), and the inserting rod (142) is movably inserted into the clamping plate (16).

8. The fully automatic optical module multi-process assembly equipment according to claim 7, wherein: the outer end fixedly connected with connection piece (17) of connecting rack (143), inserted bar (142) fixed connection is at the surface of connection piece (17), the opposite side fixedly connected with locating lever (18) of connection piece (17), locating lever (18) activity is pegged graft in the inside of fixing base (141), the side fixedly connected with gag lever post (19) of connecting rack (143), reset spring (20) have been cup jointed in the surface activity of gag lever post (19), the other end activity of gag lever post (19) is pegged graft inside connecting rack (143) of relative one side.