CN212044470U - Material taking device of optical device TO crimping machine in 100G optical module - Google Patents

Abstract

The utility model discloses a material taking device of an optical device TO crimping machine in a 100G optical module, which comprises a workbench, wherein a material box for containing a TOSA is arranged on the workbench; the feeding device is used for taking out the TOSA in the material box below the feeding device; the moving device is used for driving the TOSAs in the material box to move below the feeding device one by one; multistation rotating device for receive TOSA among the feed arrangement, and rotate TOSA to the place that needs the crimping, still include a plurality of anchor clamps, anchor clamps include left anchor clamps bracer and right anchor clamps bracer, rotate between left anchor clamps bracer and the right anchor clamps bracer and be connected with the buffering material frame, wear to be equipped with the connecting rod on the buffering material frame, the one end of connecting rod is connected with the suction head that is used for absorbing TOSA, the other end is fixed with the back push pedal, be fixed with first spring between back push pedal and the buffering material frame. The utility model discloses a mutually supporting between feed arrangement, mobile device and the multistation rotating device realizes TOSA's automation and gets the material, has improved crimping efficiency.

Description

Material taking device of optical device TO crimping machine in 100G optical module

Technical Field

The utility model belongs TO the field of optical device's manufacturing, more specifically the extracting device that relates TO optical device TO press-connection machine in the 100G optical module that says so.

Background

In the field of optical communication device production, an optical active device is a key device for converting an electric signal into an optical signal or converting the optical signal into the electric signal in an optical communication system, is a heart of an optical transmission system, and is basically used for coupling and fixing an optical path which is determined by a device body (Base); the Optical transmission module can be divided into a single-mode Optical transmission module and a multi-mode Optical transmission module, and the whole product architecture comprises an Optical sub-assembly (OSA) and an electronic sub-assembly (ESA); the optical sub-module OSA comprises a transmitter optical sub-module TOSA and a receiver optical sub-module ROSA; the ordinary optical device OSA package member includes: LD TO-Can, PD TO-Can, LD seal welding tube body, pin adapter, etc.

As shown in fig. 1, which is an exploded schematic view of an optical device and a TOSA in the prior art, a conventional enterprise generally uses a crimping method in a connecting process of the optical device LD-TO (laser diode emitter) and the TOSA during production and processing, the optical device is placed on a fixture during crimping, then the TOSA is manually placed above the optical device, and the TOSA and the optical device are crimped through a crimping structure, but the TOSA needs TO be manually taken out one by one, which is inefficient.

SUMMERY OF THE UTILITY MODEL

Not enough TO prior art, the utility model provides a extracting device of optical device TO press-connection machine in 100G optical module has made things convenient for getting of TOSA, has increased crimping efficiency.

In order to achieve the above purpose, the utility model provides a following technical scheme: the material taking device of the optical device TO crimping machine in the 100G optical module,

the device comprises a workbench, wherein a material box for containing a TOSA is arranged on the workbench;

the feeding device comprises a clamp, a transverse pushing device for driving the clamp to move transversely, a vertical pushing device for driving the clamp to move vertically and a first rotating device for driving the clamp to rotate;

the moving device is used for driving the TOSAs in the material box to move below the feeding device one by one;

the multi-station rotating device comprises a rotating platform which is rotatably connected with the workbench and a clamp which is fixed on the rotating platform.

Further, anchor clamps include left anchor clamps bracer and right anchor clamps bracer, it is connected with the buffering material frame to rotate between left anchor clamps bracer and the right anchor clamps bracer, wear to be equipped with the connecting rod on the buffering material frame, the one end of connecting rod is connected with the suction head that is used for absorbing TOSA, and the other end is fixed with the back push pedal, be fixed with first spring between back push pedal and the buffering material frame.

Further, feed arrangement is including fixing the feeding support on the workstation, one anchor clamps pass through the feeding support to be fixed on the workstation, first rotary device can drive the rotation of buffering material frame, horizontal thrust unit can drive back push pedal lateral shifting, vertical thrust unit can drive back push pedal vertical shifting.

Furthermore, the multi-station rotating device further comprises a driving motor for driving the rotating platform to rotate, at least one of the clamps is fixed on the rotating platform, and a second rotating device for driving a buffer material frame of the clamps on the rotating platform to rotate is further arranged on the workbench.

Further, feed arrangement is including setting up left feed arrangement and the right feed arrangement in the multistation rotating device left and right sides respectively, the last three anchor clamps of getting that distribute around the rotating platform axis circumference that are equipped with of rotating platform, three anchor clamps of getting are including first get the material anchor clamps, second get the material anchor clamps and third get the material anchor clamps.

Furthermore, the moving device comprises a solid material box arranged on the workbench, a transverse driving device for driving the solid material box to transversely move and a longitudinal driving device for driving the solid material box to longitudinally move, a placing groove is formed in the fixed box, and the material box is placed in the placing groove.

Furthermore, the outer wall of the rotating platform is fixedly provided with induction sheets which correspond to the clamps one to one, and the workbench is fixedly provided with inductors for inducing the induction sheets.

Furthermore, a plurality of slotted holes are formed in the material box, the slotted hole rectangular array is arranged on the material box, and the TOSA is placed in the slotted holes.

Further, the below worker of rotating platform is equipped with the rotation supporting mechanism, the rotation supporting mechanism is including fixing the brace table on the workstation, be fixed with the bearing support pole on the brace table, it is connected with supporting bearing to rotate on the bearing support pole, supporting bearing's outer wall is tangent with rotating platform's downside.

To sum up, the utility model has the advantages that:

1. through the mutual matching among the feeding device, the moving device and the multi-station rotating device, the automatic material taking of the TOSA is realized, and the crimping efficiency is improved;

2. the first rotating device can control the rotation of the steering connectors of the plurality of clamps of the multi-station rotating device, and the structure is simple and compact;

3. the multi-station rotating device is matched with the two feeding devices, so that the material taking efficiency is improved, materials are taken in the crimping process, and the time is greatly saved.

Drawings

FIG. 1 is a schematic view of a reclaimer assembly;

FIG. 2 is a schematic structural view of a feeding device;

FIG. 3 is an exploded view of a mobile device;

FIG. 4 is an exploded view of another angle of the mobile device;

FIG. 5 is a schematic view of the structure of the clamp;

FIG. 6 is a schematic structural view of a multi-station rotating device;

FIG. 7 is a schematic view of the position of line A, with the TOSAs in the material box being sequentially removed in the direction of the line A arrow;

FIG. 8 is a schematic structural view of a first rotating device;

fig. 9 is a schematic view of a connection structure of the sensing piece and the sensor.

Reference numerals: 1. a material box; 2. a TOSA; 3. a platen; 4. a crimping cylinder; 5. pressing a plate; 6. a work table; 7. a column; 8. a first TOSA; 9. a second TOSA; 10. a third TOSA; 11. a fourth TOSA;

100. a clamp; 101. a rear push plate; 102. a first spring; 103. a connecting rod; 104. a right clamp brace; 105. a right rotating shaft; 106. rotating the limiting groove; 107. a steering connector; 108. a first suction head; 109. a gas pipe connector; 110. a second spring; 111. a front baffle; 112. a left clamp brace; 113. a second hollow channel; 114. a front push plate; 115. a first hollow groove; 116. buffering the material frame; 117. fixing the air pipe;

200. a feeding device; 201. a vertical push cylinder; 202. a feed rotary cylinder; 203. a limiting plate; 204. a feed support; 205. a transverse pushing cylinder; 206. a left feed device; 207. a right feeding device;

300. a mobile device; 301. a transverse linear motor; 302. a fixed block; 303. fixing the rod; 304. a transverse push plate; 305. an avoidance groove; 306. a longitudinal push plate; 307. a first magnetic stripe; 308. a longitudinal linear motor; 309. a placement groove; 310. a solid material box; 311. a sliding table; 312. a ball bearing; 313. a transverse magnetic stripe; 314. fixing the magnetic strip; 315. a third magnetic stripe; 316. a fourth magnetic stripe; 317. a second magnetic stripe;

400. a multi-station rotating device; 401. rotating the platform; 402. an induction sheet; 403. a bearing support rod; 404. a support table; 405. a support bearing; 406. a drive motor; 407. a crimping rotary cylinder; 408. a crimping pushing cylinder; 409. crimping the bracket; 410. pressing and connecting the rotary limiting plate; 411. an inductor; 412. a first material taking clamp; 413. a second material taking clamp; 414. and a third material taking clamp.

Detailed Description

The embodiment of the material taking device of the optical device TO crimping machine in the 100G optical module of the present invention is further described with reference TO fig. 1 TO 9.

As shown in fig. 1, the material taking device of the optical device TO press-connection machine in the 100G optical module,

the device comprises a workbench 6, wherein a material box 1 for containing TOSA2 is arranged on the workbench 6;

the feeding device 200 comprises a clamp 100, a transverse pushing device for driving the clamp 100 to move transversely, a vertical pushing device for driving the clamp 100 to move vertically, and a first rotating device 415 for driving the clamp 100 to rotate;

the moving device is used for driving the TOSA2 in the material box 1 to move to the lower part of the feeding device 200 one by one;

the multi-station rotating device comprises a rotating platform 401 which is rotatably connected with the workbench 6 and a clamp 100 which is fixed on the rotating platform 401.

As shown in fig. 5, the clamp 100 includes a left clamp supporting block 112 and a right clamp supporting block 104, a buffer material frame 116 is rotatably connected between the left clamp supporting block 112 and the right clamp supporting block 104, a first hollow groove 115 with a forward opening is formed on the buffer material frame 116, two through holes are formed on the rear side wall of the buffer material frame 116, connecting rods 103 are respectively penetrated through the two through holes, a front push plate 114 is fixed on the front ends of the two connecting rods 103, a rear push plate 101 is fixed on the rear ends of the two connecting rods 103, the rear push plate 101 is arranged behind the buffer material frame 116, the front push plate 114 is arranged in the first hollow groove 115, a first spring 102 is fixed between the rear push plate 101 and the buffer material frame 116, the first spring 102 is sleeved on the connecting rods 103, a second hollow groove 113 with a forward opening is formed on the front push plate 114, a front baffle 111 is inserted in the second hollow groove 113, a second spring 110 is fixed between the front baffle 111 and the bottom surface of the second, the front side surface of the front baffle 111 is fixedly provided with a first suction head 108 for sucking the TOSA2, the rear side surface of the front baffle 111 is fixedly provided with an air pipe connector 109 coaxial with the first suction head 108, the first suction head 108 is communicated with the air pipe connector 109, a fixed air pipe 117 is fixed on the air pipe connector 109, the fixed air pipe 117 sequentially penetrates through the front push plate 114 and the buffer frame 116, one end, far away from the air pipe connector 109, of the fixed air pipe 117 is connected with a negative pressure machine through a pipeline, the pipeline is provided with a controller, the controller can control whether the first suction head 108 generates negative pressure, when the controller controls the first suction head 108 to generate negative pressure, the first suction head 108 can suck the TOSA2, at the moment, a receiving pipeline of the TOSA2 is in the first suction head 108, and a pipe cap is positioned on.

As shown in fig. 5, a right rotating shaft 105 is fixed on the right side of the buffering material frame 116, the right rotating shaft 105 penetrates through the right clamp supporting block 104 to be rotatably connected with the right clamp supporting block 104, a left rotating shaft is fixed on the left side of the buffering material frame 116, the left rotating shaft penetrates through the left clamp supporting block 112 to be rotatably connected with the left clamp supporting block 112, the right end of the right rotating shaft 105 penetrates through the right clamp supporting block 104 and is fixed with a steering connector 107, a rotation limiting groove 106 is arranged on the steering connector 107, and the rotation limiting groove 106 is preferably in a straight shape.

As shown in fig. 2 and 5, the feeding device 200 includes a feeding support 204 fixed on the workbench 6, the left clamp supporting block 112 and the right clamp supporting block 104 of one clamp 100 are fixed on the workbench 6 through the feeding support 204, the first rotating device can drive the buffer material frame 116 to rotate, the transverse pushing device can drive the rear push plate 101 to move transversely, and the vertical pushing device can drive the rear push plate 101 to move vertically; the first rotating device comprises a feeding rotating cylinder 202 fixed on the workbench 6, a limiting plate 203 inserted with a rotating limiting groove 106 in the clamp 100 of the feeding device 200 is fixed on a rotating shaft of the feeding rotating cylinder 202, and the limiting plate 203 is in a straight shape; the transverse pushing device comprises a transverse pushing cylinder 205 fixed on the workbench 6, when the first suction head 108 is in a horizontal state, a pushing plate fixed on a pushing rod of the transverse pushing cylinder 205 can push the rear pushing plate 101 to move transversely, so that the connecting rod 103 moves towards the multi-station rotating device 400, but the pushing plate is not fixed with the rear pushing plate 101; be fixed with platen 3 through stand 7 on the workstation 6, vertical thrust unit is including fixing vertical push cylinder 201 on platen 3, and when first suction head 108 rotated vertical down, vertical push cylinder 201 can drive first suction head 108 downstream to get the TOSA on the workstation 6.

As shown in fig. 3 and 4, the moving device 300 includes a solid material box 310 placed on the working table 6, a transverse driving device for driving the solid material box 310 to move transversely, and a longitudinal driving device for driving the solid material box 310 to move longitudinally, a placing groove 309 is provided on the fixed box, and the material box 1 is placed in the placing groove 309.

As shown in fig. 3 and 4, the moving device 300 further includes a sliding table 311 fixed on the workbench 6, the sliding table 311 is provided with a plurality of sliding grooves, balls 312 are rotatably connected in the sliding grooves, a fixing box 310 is placed above the balls 312, the balls 312 enable the fixing box 310 to move more smoothly on the sliding table 311, the fixing box 310 is provided with a placing groove 309 for placing the material box 1, TOSA2 is placed in a plurality of slotted holes of the material box 1, slotted hole rectangles are arranged on the material box 1 in an array, caps of the TOSA2 face up, the workbench 6 is provided with a transverse driving structure for driving the fixing box 310 to move transversely on the balls 312, and the workbench 6 is further provided with a longitudinal driving structure for driving the fixing box 310 to move longitudinally on the balls 312.

As shown in fig. 3 and 4, the longitudinal driving structure includes a longitudinal linear motor 308 fixed on the worktable 6, a longitudinal push plate 306 is fixed on a push rod of the longitudinal linear motor 308, and the push rod of the longitudinal linear motor 308 can drive the longitudinal push plate 306 to move longitudinally; the transverse driving structure comprises a transverse linear motor 301 fixed on the workbench 6, a transverse push plate 304 is fixed on a push rod of the transverse linear motor 301, the push rod of the transverse linear motor 301 can drive the transverse push plate 304 to transversely move, the transverse push plate 304 comprises a transverse fixed block 302 and two mutually parallel fixed rods 303 fixed on the transverse fixed block 302, an avoiding groove 305 for the longitudinal push plate 306 to be plugged is formed between the two fixed rods 303, the height of the longitudinal push plate 306 is smaller than that of the avoiding groove 305, and the avoiding groove 305 can prevent the transverse push plate 304 and the longitudinal push plate 306 from interfering when moving.

As shown in fig. 3 and 4, a first magnetic stripe 307 is fixed on the side of the longitudinal push plate 306 facing the solid material box 310, a second magnetic stripe 317 adsorbed with the first magnetic stripe 307 is fixed on the side of the solid material box 310 facing the longitudinal push plate 306, and the first magnetic stripe 307 and the second magnetic stripe 317 are both in a long strip shape; a third magnetic stripe 315 is fixed on the side of the transverse push plate 304 facing the solid material box 310, a fourth magnetic stripe 316 adsorbed with the third magnetic stripe 315 is fixed on the side of the solid material box 310 facing the transverse push plate 304, the third magnetic stripe 315 comprises two transverse magnetic stripes 313 respectively fixed on the two fixing rods 303, the third magnetic stripe 315 further comprises a fixing magnetic stripe 314 fixed on the fixing block 302, and the shape of the fourth magnetic stripe 316 is C-shaped or long; accurate positioning of the TOSA2 in the material box 1 can be achieved by the movement of the push rods of the longitudinal linear motor 308 and the transverse linear motor 301.

The operation principle of the feeding device is as follows: the first suction head 108 of the clamp 100 of the feeding device 200 takes out the first TOSA8 in the material box 1 and then conveys the same to the multi-station rotating device 400, then the longitudinal push plate 306 of the longitudinal linear motor 308 drives the solid material box 310 to move longitudinally, during the pushing process, the solid material box 310 slides relative to the transverse push plate 304, so that the second TOSA9 moves below the first suction head 108 of the clamp 100, the first suction head 108 of the clamp of the feeding device 200 takes out the second TOSA9 in the material box 1 and then conveys the same to the multi-station rotating device 400, the process is repeated until the last third TOSA10 in the row of the first TOSA8 and the second TOSA9 completes the conveying, then the transverse push plate 304 of the transverse linear motor 301 drives the solid material box 310 to move transversely, so that the fourth TOSA11 moves below the first suction head 108 of the clamp 100, then the fourth TOSA11 conveys, then the longitudinal linear motor 308 drives the solid material box 310 to move in the direction opposite to the longitudinal direction, so that the TOSAs 2 in the column of the fourth TOSA11 can be transmitted one by one; according to the above method, the TOSAs 2 are transferred one by one in the order of the a-line direction in fig. 7, thereby completing the transfer of the TOSAs 2 in the material cassette 1.

As shown in fig. 1 and fig. 6, the multi-station rotating device 400 includes a driving motor 406 for driving the rotating platform 401 to rotate, at least one clamp 100 is fixed on the rotating platform 401, and a second rotating device for driving the buffer frame 116 of the clamp 100 on the rotating platform 401 to rotate is further disposed on the working platform 6.

As shown in fig. 6, the second rotating device 415 includes a crimping rotary cylinder 407 and a crimping push cylinder 408, the crimping push cylinder 408 is fixed on the lower side surface of the platen 3, a push rod of the crimping push cylinder 408 is fixedly connected with a housing of the crimping rotary cylinder 407 through a crimping bracket 409, a rotating shaft of the crimping rotary cylinder 407 is fixed with a crimping rotary limiting plate 410, the push rod of the crimping push cylinder 408 drives the crimping rotary limiting plate 410 to be inserted into the rotary limiting groove 106 of the clamp 100 on the multi-station rotating device 400, the crimping rotary cylinder 407 can drive the first suction head 108 of the clamp 100 to rotate to a vertical state, at this time, the rear push plate 101 can be pushed to drive the TOSA2 to move downward, the TOSA2 is crimped with the optical device placed on the worktable 6, when a next optical device is to be crimped, the crimping push cylinder 408 first drives the crimping rotary limiting plate 410 of the crimping rotary cylinder 407 to leave the inserted rotary limiting groove 106, after the next fixture 100 rotates to the crimping station, the crimping rotation limiting plate 410 of the crimping rotation cylinder 407 is driven to be inserted into the rotation limiting groove 106 of the steering connector 107 of the fixture 100 at the crimping station, and one second rotating device 415 can control the rotation of the steering connectors 107 of the plurality of fixtures 100.

As shown in fig. 6 and 9, L-shaped sensing pieces 402 corresponding to the jigs 100 one by one are fixed on the outer wall of the rotating platform 401, a U-shaped sensor 411 for sensing the L-shaped sensing pieces 402 is fixed on the worktable 6, the model of the U-shaped sensor 411 is a photoelectric sensor PM-Y45, the L-shaped sensing pieces 402 pass through the U-shaped sensor 411, the U-shaped sensor 411 sends a signal to the driving motor 406, the driving motor 406 stops rotating, at this time, the crimping action is performed, and after the crimping is completed, the driving motor 406 can continue to drive the rotating platform 401 to rotate, so that the next jig 100 moves to the crimping position, and the rotating angle of the rotating platform 401 is more accurate; the lower worker of rotary platform 401 is equipped with rotation supporting mechanism, and rotation supporting mechanism is fixed with bearing support bar 403 including fixing the brace table 404 on workstation 6 on the brace table 404, rotates on the bearing support bar 403 and is connected with supporting bearing 405, and supporting bearing 405's inner wall and bearing support bar 403 fixed connection, supporting bearing 405's outer wall is tangent with rotary platform 401's downside.

As shown in fig. 1, the feeding device 200 includes a left feeding device 206 and a right feeding device 207 which are arranged on the left side and the right side of the multi-station rotating device 400 and have the same structure, the rotating platform 401 is provided with three material taking clamps 100 distributed around the circumference of the axis of the rotating platform 401, each of the three material taking clamps 100 includes a first material taking clamp 412, a second material taking clamp 413 and a third material taking clamp 414, an included angle between each of the first material taking clamp 412 and the second material taking clamp 413 and the axis of the rotating platform 401 is set to be 90 °, and an included angle between each of the second material taking clamp 414 and the axis of the rotating platform 401 is set to be 90 °.

As shown in fig. 1, a pressing cylinder 4 is further fixed on the platen 3, a pressing plate 5 is fixed on a push rod of the pressing cylinder 4 and used for pushing a rear pushing plate 101 of the clamp on the multi-station rotating device 400, the pressing plate 5 of the pressing cylinder 4 moves downward, and the TOSA on the clamp is pressed with the optical device placed on the workbench by pushing the rear pushing plate 101.

The control method of the material taking device of the optical device TO crimping machine in the 100G optical module comprises the following steps:

s1: the left feeding device 206 takes out the TOSA2 in the material box 1 below the left feeding device, the moving device 300 drives the next TOSA2 in the material box 1 below the moving device to stand, the right feeding device 207 takes out the TOSA2 in the material box 1 below the moving device, and the moving device 300 drives the next TOSA2 in the material box 1 to stand;

s2: the left feed device 206 delivers the TOSA2 to the first take out fixture 412, and the right feed device 207 delivers the TOSA2 to the third take out fixture 414;

s3: the driving motor 406 drives the rotating platform 401 to rotate clockwise, the third material taking clamp 414 rotates to a place needing compression joint, the first rotating device 415 drives the first buffer material frame 116 of the third material taking clamp 414 to rotate anticlockwise until the vertical direction of the first suction head 108 is aligned with the optical device on the workbench 6, the pressing plate 5 of the compression joint cylinder 4 drives the rear pressing plate 101 of the third material taking clamp 100 to move downwards to compress and joint the optical device placed on the workbench 6, and after compression joint of one optical device is completed, the left feeding device 206 takes out the TOSA2 in the material box 1 below the left feeding device and conveys the TOSA2 to the second material taking clamp 413;

s4: the driving motor 406 drives the rotating platform 401 to rotate counterclockwise, the second material taking clamp 413 rotates to a place needing compression joint, the first rotating device 415 drives the first buffer material frame 116 of the second material taking clamp 100 to rotate counterclockwise and then perform compression joint, and after compression joint of another optical device is completed, the right feeding device 207 takes out the TOSA2 in the material box 1 below the second material taking clamp and conveys the TOSA2 to the third material taking clamp 414;

s5: the driving motor 406 drives the rotating platform 401 to rotate anticlockwise, the first material taking clamp 412 rotates to a place needing compression joint, the first rotating device 415 drives the first buffer material frame 116 of the first material taking clamp 412 to rotate anticlockwise and then carry out compression joint, and meanwhile the right feeding device 207 takes out the TOSA2 in the material box 1 below the TOSA2 and conveys the TOSA2 to the second material taking clamp 413;

s6: the driving motor 406 drives the rotating platform 401 to rotate clockwise, the second material taking fixture 100 rotates to a place needing crimping, the first rotating device 415 drives the first buffer material frame 116 of the second material taking fixture 413 to rotate anticlockwise and then conduct crimping, meanwhile, the left feeding device 206 takes out the TOSA2 in the material box 1 below the TOSA2 and conveys the TOSA2 to the first material taking fixture 412, and then the process goes to S3.

It is above only the utility model discloses a preferred embodiment, the utility model discloses a scope of protection does not only confine above-mentioned embodiment, the all belongs to the utility model discloses a technical scheme under the thinking all belongs to the utility model discloses a scope of protection. It should be noted that, for those skilled in the art, various modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (9)

1.extracting device of optical device TO press-connection machine in 100G optical module, its characterized in that:

the device comprises a workbench, wherein a material box for containing a TOSA is arranged on the workbench;

the feeding device comprises a clamp, a transverse pushing device for driving the clamp to move transversely, a vertical pushing device for driving the clamp to move vertically and a first rotating device for driving the clamp to rotate;

the moving device is used for driving the TOSAs in the material box to move below the feeding device one by one;

the multi-station rotating device comprises a rotating platform which is rotatably connected with the workbench and a clamp which is fixed on the rotating platform.

2. The extracting device of optical device TO press-connection machine in 100G optical module of claim 1, characterized in that: anchor clamps include left anchor clamps bracer and right anchor clamps bracer, it is connected with the buffering material frame to rotate between left anchor clamps bracer and the right anchor clamps bracer, wear to be equipped with the connecting rod on the buffering material frame, the one end of connecting rod is connected with the suction head that is used for absorbing TOSA, and the other end is fixed with the back push pedal, be fixed with first spring between back push pedal and the buffering material frame.

3. The extracting device of optical device TO press-connection machine in 100G optical module of claim 2, characterized in that: the feeding device comprises a feeding support fixed on the workbench, one fixture is fixed on the workbench through the feeding support, the first rotating device can drive the buffering material frame to rotate, the transverse pushing device can drive the rear push plate to move transversely, and the vertical pushing device can drive the rear push plate to move vertically.

4. The extracting device of optical device TO press-connection machine in 100G optical module of claim 3, characterized in that: the multi-station rotating device further comprises a driving motor for driving the rotating platform to rotate, at least one fixture is fixed on the rotating platform, and a second rotating device for driving a buffering material frame of the fixture on the rotating platform to rotate is further arranged on the workbench.

5. The extracting device of optical device TO press-connection machine in 100G optical module of claim 4, characterized in that: the feeding device comprises a left feeding device and a right feeding device which are respectively arranged on the left side and the right side of the multi-station rotating device, three material taking clamps which are distributed around the circumference of the axis of the rotating platform are arranged on the rotating platform, and each three material taking clamp comprises a first material taking clamp, a second material taking clamp and a third material taking clamp.

6. The extracting device of optical device TO press-connection machine in 100G optical module of claim 1, characterized in that: the moving device comprises a solid material box arranged on the workbench, a transverse driving device for driving the solid material box to transversely move and a longitudinal driving device for driving the solid material box to longitudinally move, wherein a placing groove is formed in the solid material box, and the material box is placed in the placing groove.

7. The extracting device of optical device TO press-connection machine in 100G optical module of claim 4, characterized in that: the outer wall of the rotating platform is fixedly provided with induction sheets which correspond to the clamps one to one, and the workbench is fixedly provided with inductors used for inducing the induction sheets.

8. The extracting device of optical device TO press-connection machine in 100G optical module of claim 1, characterized in that: the material box is provided with a plurality of slotted holes, the slotted hole rectangular array is arranged on the material box, and the TOSA is placed in the slotted holes.

9. The extracting device of optical device TO press-connection machine in 100G optical module of claim 4, characterized in that: the utility model discloses a rotary platform, including the workstation, the workstation is equipped with the below worker of rotary platform, the support platform is fixed with the bearing support pole on the workstation including fixing to the support mechanism, it is connected with supporting bearing to rotate on the bearing support pole, supporting bearing's outer wall is tangent with rotary platform's downside.

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