CN111679375A

CN111679375A - Optical fiber interface equipment check out test set

Info

Publication number: CN111679375A
Application number: CN202010540766.4A
Authority: CN
Inventors: 蔡伟美
Original assignee: Wenzhou Polytechnic
Current assignee: Wenzhou Polytechnic
Priority date: 2020-06-15
Filing date: 2020-06-15
Publication date: 2020-09-18

Abstract

The invention relates to an optical fiber interface assembly detection device, which comprises a rack and a platform arranged on the rack; the automatic feeding device is characterized in that the platform comprises a main turntable assembly, a base feeding assembly, a spring feeding assembly, an inserting core feeding assembly, a shell feeding assembly, a dustproof cap feeding assembly and an inserting core turntable assembly, wherein the inserting core turntable assembly is arranged on the platform through an inserting core indexing mechanism, a supporting plate for inserting cores is arranged at the fixed end of the inserting core indexing mechanism, and a collecting assembly used for guiding the inserting core of the inserting core feeding mechanism and collecting an inserting core protective sleeve is arranged in the supporting plate for inserting cores. The optical fiber interface assembly detection equipment can combine the operations of the base, the spring, the inserting core, the shell and the dust cap into a whole, and realizes automatic installation.

Description

Optical fiber interface equipment check out test set

Technical Field

The invention relates to the technical field of optical fiber connector assembly, in particular to optical fiber interface assembly detection equipment.

Background

The optical fiber connector comprises a base, a spring, an inserting core, a shell and a dustproof cap, in the common assembling process, each installation operation is separated and independent, corresponding detection means are arranged in each operation, the detection means are collected together after the detection is finished, the next procedure is continuously installed, the base, the spring, the inserting core, the shell and the dustproof cap are installed according to the sequence of the base, the spring, the inserting core, the shell and the dustproof cap, a finished product is finally formed, a large amount of manpower and material resources are occupied after the procedures are too many, the efficiency is lower, and the automation degree is low.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide optical fiber interface assembly detection equipment which can combine the operations of a base, a spring, a ferrule, a shell and a dust cap into a whole to realize automatic installation.

The above functions of the invention are realized by the following technical scheme:

an optical fiber interface assembly detection device comprises a rack and a platform arranged on the rack;

the main turntable assembly is arranged on the platform through a main dividing mechanism, and a main supporting plate is arranged at the fixed end of the main dividing mechanism;

the base feeding assembly is butted with a base mounting station arranged on the main turntable assembly, and a base is clamped to a mounting position through the base mounting station;

the spring feeding assembly is butted with a spring mounting station arranged on the main turntable assembly, and the spring is mounted and fixed in the base through the spring mounting station;

the ferrule feeding assembly is butted with a ferrule mounting station arranged on the main turntable assembly, and the ferrule is mounted on the optical fiber semi-finished product after the spring mounting station is finished through the ferrule mounting station;

the shell feeding assembly is butted with a shell mounting station arranged on the main turntable assembly, and the shell is mounted on the optical fiber semi-finished product after the shell mounting station is finished through the shell mounting station;

the dustproof cap feeding assembly is butted with a dustproof cap mounting station arranged on the main turntable assembly, and the dustproof cap is mounted on the optical fiber semi-finished product after the shell mounting station is finished through the dustproof cap mounting station;

the finished product blanking assembly is butted with a finished product blanking station arranged on the main turntable assembly, and a finished product is moved into a finished product supporting plate through a blanking manipulator;

the ferrule feeding assembly comprises a ferrule rotary disc assembly and a ferrule feeding mechanism in butt joint fit with the ferrule rotary disc assembly;

the turntable assembly for the inserting core is arranged on the platform through the indexing mechanism for the inserting core, a supporting plate for the inserting core is arranged at the fixed end of the indexing mechanism for the inserting core, and an inserting core guide assembly for the inserting core feeding mechanism and a collecting assembly for collecting an inserting core protective sleeve are arranged in the supporting plate for the inserting core.

Preferably, the main turntable assembly comprises a main turntable and sixteen feeding tool fixtures which are uniformly distributed in the main turntable;

the main supporting plate is fixedly arranged in the fixed end of the main indexing mechanism through a main cushion high fixing block and can keep static above the main indexing mechanism;

the main indexing mechanism is a sixteen-indexing divider which works in a rotary indexing mode through the action of a main speed reducer.

Preferably, the ferrule feeding mechanism comprises a T-shaped support rod arranged on the platform, an XY-axis sliding table for ferrules arranged on the T-shaped support rod, an L-shaped connecting block for ferrules arranged on the XY-axis sliding table in the X-axis direction, an air nozzle for ferrules arranged in the L-shaped connecting block for ferrules and used for adsorbing the ferrules, a first vacuum emitter connected to the rear part of the air nozzle for ferrules, and a feeding table for ferrules arranged on one side of the turntable assembly for ferrules;

the rotary table component for the inserting core comprises a rotary table for the inserting core and sixteen inserting core tool clamps which are uniformly distributed in the rotary table for the inserting core and used for fixing the inserting core, wherein the bottom of each inserting core tool clamp is provided with a second vacuum emitter used for adsorbing the inserting core;

the supporting plate for the inserting core is arranged in a fixed end of the indexing mechanism for the inserting core through the heightening fixed block for the inserting core, and can keep static on the indexing mechanism for the inserting core;

the indexing mechanism for the inserting core is a sixteen-indexing divider which can rotate and index through the action of a speed reducer for the inserting core;

the collection subassembly of collecting the lock pin protective sheath is including collecting XY axle slip table for the lock pin protection cover, setting and collecting the lock pin protection cover in the X axle direction of XY axle slip table for the lock pin protection cover and using die clamping cylinder, sets up and is collecting the anchor clamps that the lock pin protection cover was used for die clamping cylinder output and is used for pressing from both sides the clamp protective sheath.

Preferably, the base feeding assembly comprises a base raw material vibrating disk, a base raw material feeding rail matched with the base raw material vibrating disk, and a base jacking assembly which is butted with the base raw material feeding rail and used for jacking the base for feeding;

the base jacking assembly comprises a base jacking supporting seat, a base jacking supporting frame arranged on the base jacking supporting seat, a base jacking air cylinder arranged on the base jacking supporting frame, and a base jacking seat arranged at the output end of the base jacking air cylinder and used for jacking the base;

the base mounting station comprises an XY axis sliding table for base mounting, a clamping cylinder for base mounting arranged in the X axis direction of the XY axis sliding table for base mounting, and a clamp for base mounting arranged on the clamping cylinder for base mounting;

the platform is also provided with a base existence detection station arranged in the main supporting plate and a base adjusting station arranged on the main supporting plate;

the base existence detection station comprises a base existence detection CDD detection lens and a lens connecting plate for fixing the position of the base existence detection CDD detection lens, the lens connecting plate is fixedly arranged at the lower end of the main supporting plate, and the base existence detection CDD detection lens is aligned to the feeding tool clamp;

the base adjustment station comprises an X-axis sliding table for base adjustment, a rotary cylinder for base adjustment arranged on the X-axis sliding table for base adjustment, and a rotary fixture for base adjustment arranged at the output end of the rotary cylinder for base adjustment.

Preferably, the spring feeding assembly comprises a spring raw material vibrating disk, a spring raw material feeding rail matched with the spring raw material vibrating disk, and a base jacking assembly which is butted with the spring raw material feeding rail and used for jacking the spring for feeding;

the spring jacking assembly comprises a supporting seat for spring jacking, a supporting frame for spring jacking arranged on the supporting seat for spring jacking, a cylinder for spring jacking arranged on the supporting frame for spring jacking, and a spring jacking seat arranged at the output end of the cylinder for spring jacking and used for jacking a spring, wherein a jacking contact pin matched with the spring is arranged on the spring jacking seat, and the tail end of the jacking contact pin is provided with a conical surface;

the spring mounting station comprises an XY-axis sliding table for mounting a spring, a clamping cylinder for mounting the spring, a clamp for mounting the spring, and a spring guide assembly, wherein the clamping cylinder is arranged in the X-axis direction of the XY-axis sliding table for mounting the spring;

the spring guide assembly comprises a support plate for spring guide arranged below the main support plate, a clamping cylinder for spring guide arranged on the support plate for spring guide, and a spring guide clamp arranged at the output end of the clamping cylinder for spring guide;

a spring presence detection station is further arranged on the platform; the spring has or not to detect the station including being provided with the main tributary fagging below the spring have or not to detect with connecting plate, set up the spring that the spring has or not to detect on the connecting plate with the spring has or not to detect with the CDD inspection camera lens, the spring has or not to detect with the CDD inspection camera lens and aims at material loading frock clamp.

Preferably, the ferrule mounting station comprises an XY-axis sliding table for mounting the ferrule, a clamping cylinder for mounting the ferrule arranged in the X-axis direction of the XY-axis sliding table for mounting the ferrule, a clamp for mounting the ferrule arranged on the clamping cylinder for mounting the ferrule, and a ferrule guide assembly arranged below the main supporting plate;

the ferrule guide assembly comprises a ferrule guide support plate arranged below the main support plate, a ferrule guide clamping cylinder arranged on the ferrule guide support plate, and a ferrule guide clamp arranged at the output end of the ferrule guide clamping cylinder;

the platform is also provided with a core insert adjusting station and a core insert clamping assembly;

the ferrule adjusting station comprises a ferrule adjusting cylinder, a ferrule adjusting connecting plate arranged at the output end of the ferrule adjusting cylinder, and a ferrule adjusting block arranged on the ferrule adjusting connecting plate, wherein the ferrule adjusting block is provided with an adjusting inclined surface for adjusting the position of a ferrule;

the ferrule clamping assembly comprises a supporting seat for clamping the ferrule, a clamping cylinder for clamping the ferrule arranged on the supporting seat for clamping the ferrule, and a clamp for clamping the ferrule arranged at the output end of the clamping cylinder for clamping the ferrule.

Preferably, the shell feeding assembly comprises a shell raw material vibrating disc, a shell raw material feeding rail matched with the shell raw material vibrating disc, and a pushing assembly for pushing a shell on the shell raw material feeding rail, wherein the pushing assembly comprises a supporting seat for pushing, a pushing material channel arranged on the supporting seat for pushing, and a pushing cylinder arranged on the pushing material channel, and the pushing cylinder is abutted to the shell through a pushing plate;

the shell mounting station comprises an XY axis sliding table for mounting the shell, a clamping cylinder for mounting the shell arranged in the X axis direction of the XY axis sliding table for mounting the shell, and a clamp for mounting the inserting core arranged on the clamping cylinder for mounting the shell;

the platform is also provided with a shell compacting station and a shell in-place detection station, wherein the shell compacting station and the shell in-place detection station are used for installing the shell in place;

the shell compacting station comprises a shell compacting component arranged above the main supporting plate and a shell guide component arranged below the main supporting plate,

the shell compacting assembly comprises a shell compacting practical connecting plate arranged above the main support plate, a shell compacting practical air cylinder arranged at the tail end of the shell compacting practical connecting plate and a shell compacting rod arranged at the output end of the shell compacting practical air cylinder, and the axis of the shell compacting rod is hollow;

the shell guide assembly comprises a shell guide supporting plate arranged below the main supporting plate, a shell guide clamping cylinder arranged on the shell guide supporting plate, and a shell guide clamp arranged at the output end of the shell guide clamping cylinder;

the shell detection station that targets in place detects the head including setting up the shell that targets in place above the main tributary fagging and detecting with the mount pad, setting up the shell that targets in place in the detection with the mount pad and detecting with the cylinder, setting up the shell that targets in place at the shell that detects with the cylinder output and detecting with the connecting plate, setting up the shell that targets in place in the detection with the connecting plate that detects with the shell and detecting with the detection head, the shell targets in place and detects with detecting the head and aim at material loading frock clamp.

Preferably, the platform is also provided with an elastic detection station; the elasticity detection station comprises an elasticity detection assembly and a guide clamp for elasticity detection;

the elasticity detection assembly comprises an installation seat for elasticity detection arranged above the main supporting plate, an air cylinder for elasticity detection arranged on the installation seat for elasticity detection, a connecting plate for elasticity detection arranged at the output end of the air cylinder for elasticity detection, and a detection head for elasticity detection arranged in the connecting plate for elasticity detection, wherein the detection head for elasticity detection is positioned right above the feeding tool clamp;

the elasticity detection is with leading positive anchor clamps is including setting up elasticity detection in the main tributary backup pad below and leading with the backup pad, setting up elasticity detection that elasticity detection is led on leading with the backup pad is led and is led with die clamping cylinder, setting up and leading the elasticity detection that leads with die clamping cylinder output at elasticity detection and lead positive anchor clamps.

Preferably, the dustproof cap feeding assembly comprises a dustproof cap raw material vibrating disk, a dustproof cap raw material feeding track matched with the dustproof cap raw material vibrating disk, and a dustproof cap jacking assembly which is in butt joint with the dustproof cap raw material feeding track and used for jacking up the dustproof cap for feeding;

the dustproof cap jacking assembly comprises a supporting seat for jacking the dustproof cap, a supporting frame for jacking the dustproof cap, a cylinder for jacking the dustproof cap, and a dustproof cap jacking seat, wherein the supporting frame is arranged on the supporting seat for jacking the dustproof cap;

the dustproof cap mounting station comprises an XY-axis sliding table for mounting the dustproof cap, a clamping cylinder for mounting the dustproof cap, a clamp for mounting the dustproof cap, and a dustproof cap guide assembly, wherein the clamping cylinder is arranged in the X-axis direction of the XY-axis sliding table for mounting the dustproof cap;

the dust cap guide assembly comprises a support plate for guiding the dust cap, a clamping cylinder for guiding the dust cap and arranged below the support plate for guiding the dust cap, and a dust cap guide clamp arranged at the output end of the clamping cylinder for guiding the dust cap;

still be provided with dustproof cap compaction station on setting up on the platform.

The dust cap compacting station comprises a dust cap compacting component arranged above the main support plate and a dust cap guiding component arranged below the main support plate,

the dust cap compacting assembly comprises a connecting plate for dust cap compacting, a dust cap compacting practical cylinder and a dust cap compacting rod, wherein the connecting plate is arranged above the main supporting plate;

the dustproof cap guide assembly comprises a supporting plate for guiding and correcting a dustproof cap, a clamping cylinder for guiding and correcting the dustproof cap, and a dustproof cap guide clamp, wherein the supporting plate is arranged below the main supporting plate;

preferably, the finished product blanking station comprises a T-shaped support rod arranged on the platform, a XY-axis sliding table for blanking arranged on the T-shaped support rod for blanking, an L-shaped connecting block arranged in the X-axis direction of the XY-axis sliding table for blanking, a clamping cylinder for blanking arranged in the L-shaped connecting block for blanking, a clamp for blanking arranged in the clamping cylinder for blanking, and a finished product blanking conveying table arranged on one side of the main turntable assembly;

the finished product blanking assembly comprises a finished product blanking transport platform and a finished product supporting plate arranged on the blanking transport platform.

The optical fiber interface assembly detection equipment can combine the operations of the base, the spring, the inserting core, the shell and the dust cap into a whole, and realizes automatic installation.

Drawings

FIG. 1 is a schematic top view of an optical fiber interface assembly inspection apparatus according to the present invention;

FIG. 2 is a schematic front view of an optical fiber interface assembly detection apparatus according to the present invention;

FIG. 3 is a schematic view of a three-dimensional structure of a base feeding assembly and a base mounting station of an optical fiber interface assembly detection apparatus according to the present invention;

FIG. 4 is a schematic structural diagram of a base feeding assembly of an optical fiber interface assembly detection apparatus according to the present invention, as seen from the front, cooperating with a base mounting station;

FIG. 5 is a schematic perspective view of a base mounting station of an optical fiber interface assembly inspection apparatus according to the present invention;

FIG. 6 is a schematic structural diagram of a base mounting station of an optical fiber interface assembly inspection apparatus according to the present invention;

FIG. 7 is a schematic perspective view of a spring feeding assembly and a spring mounting station of an optical fiber interface assembly detection apparatus according to the present invention;

FIG. 8 is a schematic view of a three-dimensional structure of a ferrule feeding assembly and a ferrule mounting station of an optical fiber interface assembly inspection apparatus according to the present invention;

FIG. 9 is an enlarged view of the portion A of FIG. 8;

FIG. 10 is a schematic top view of an adjusting block for adjusting a ferrule of an optical fiber interface assembly inspection apparatus according to the present invention;

FIG. 11 is a schematic perspective view of a housing feeding assembly and a housing installation station of an optical fiber interface assembly inspection apparatus according to the present invention;

FIG. 12 is a schematic front view of a housing installation station of an optical fiber interface assembly inspection apparatus according to the present invention;

FIG. 13 is a schematic structural diagram of an elastic force detection station of an optical fiber interface assembly inspection apparatus according to the present invention;

FIG. 14 is an enlarged structural view of a portion B in FIG. 13;

FIG. 15 is a schematic diagram of a dust cap feeding assembly and a dust cap installation station of an optical fiber interface assembly inspection apparatus according to the present invention;

fig. 16 is a schematic structural diagram of a finished product blanking assembly of the optical fiber interface assembly detection apparatus of the present invention cooperating with a finished product blanking station;

fig. 17 is a schematic structural diagram of a finished product blanking station of the optical fiber interface assembly detection apparatus of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1, the optical fiber interface assembly detection apparatus of the present invention includes a rack 1, and a platform 11 disposed on the rack 1;

a main turntable assembly (not shown) disposed on the platform 11 via a main indexing mechanism 92, a main supporting plate being disposed on a fixed end of the main indexing mechanism 92;

a base feeding assembly 20 which is butted with a base mounting station 2 arranged on a main turntable assembly (not shown in the figure), and clamps a base to a mounting position through the base mounting station 2;

the spring feeding assembly 30 is butted with a spring mounting station 3 arranged on a main turntable assembly (not shown), and a spring is mounted and fixed in the base through the spring mounting station 3;

the ferrule feeding assembly 400 is butted with a ferrule mounting station 4 arranged on a main turntable assembly (not marked in the figure), and the ferrule is mounted on the optical fiber semi-finished product after the spring mounting station is finished through the ferrule mounting station 4;

a housing feeding assembly 50, which is butted with a housing mounting station 5 arranged on a main turntable assembly (not shown), and the housing is mounted on the optical fiber semi-finished product after the housing mounting station is finished through the housing mounting station 5;

a dust cap feeding assembly 70 which is butted with a dust cap mounting station 7 arranged on a main turntable assembly (not marked in the figure), and the dust cap is mounted on the optical fiber semi-finished product after the shell mounting station is finished through the dust cap mounting station 7;

a finished product blanking assembly 80, which is butted with a finished product blanking station 8 arranged on a main turntable assembly (not shown), and moves a finished product into a finished product supporting plate 801 through a blanking manipulator 81;

the ferrule feeding assembly 400 comprises a ferrule rotary table assembly (not shown), and a ferrule feeding mechanism (not shown) in butt fit with the ferrule rotary table assembly (not shown);

and a ferrule rotary table assembly (not shown) disposed on the platform 11 via a ferrule indexing mechanism 47, wherein a ferrule support plate 42 is disposed at a fixed end of the ferrule indexing mechanism 47, and the ferrule support plate 42 is provided with a ferrule guide assembly (not shown) for guiding the ferrule to a ferrule feeding mechanism (not shown) and a collection assembly 48 for collecting the ferrule sleeve.

As shown in fig. 2, in the present embodiment, the main turntable assembly (not shown) includes a main turntable 9, sixteen feeding fixtures 90 disposed in the main turntable 9 and distributed uniformly; the main supporting plate 10 is fixedly arranged in the fixed end of the main indexing mechanism 92 through a main cushion high fixing block 91, and can be kept static above the main indexing mechanism 92; the main indexing mechanism 92 is a sixteen-index divider, which is driven by a main speed reducer (not shown) to perform rotary indexing.

As shown in fig. 3 and 4, in this embodiment, the base feeding assembly 20 includes a base material vibrating plate 23, a base material feeding rail 21 matched with the base material vibrating plate 23, and a base jacking assembly 22 butted with the base material feeding rail 21 and used for jacking up the base for feeding;

as shown in fig. 3 and 4, in the present embodiment, the base jacking assembly 22 includes a base jacking supporting seat 221, a base jacking supporting frame 222 disposed on the base jacking supporting seat 221, a base jacking cylinder 223 disposed on the base jacking supporting frame 222, and a base jacking seat 224 disposed at an output end of the base jacking cylinder and used for jacking the base;

as shown in fig. 3 and 4, in the present embodiment, the base mounting station 2 includes a base mounting XY-axis slide table 26, a base mounting clamp cylinder 27 provided in the X-axis direction of the base mounting XY-axis slide table 2, and a base mounting jig 28 provided on the base mounting clamp cylinder 27;

as shown in fig. 5 and 6, in this embodiment, the platform 11 is further provided with a base presence detecting station 24 disposed in the main support plate 10, a base adjusting station 25 disposed on the main support plate 11,

as shown in fig. 5 and 6, in the present embodiment, the base presence/absence detecting station 24 includes a CDD detecting lens 241 for base presence/absence detection, and a lens connecting plate 242 for fixing the position of the CDD detecting lens 241 for base presence/absence detection, the lens connecting plate 242 is fixedly disposed at the lower end of the main supporting plate 10, and the CDD detecting lens 241 for base presence/absence detection is aligned with the loading fixture 90;

as shown in fig. 5 and 6, in the present embodiment, the base adjustment station 25 includes a base adjustment X-axis slide table 251, a base adjustment rotary cylinder 252 provided on the base adjustment X-axis slide table 251, and a base adjustment rotary jig 253 provided at an output end of the base adjustment rotary cylinder.

As shown in fig. 7, in this embodiment, the spring feeding assembly 30 includes a spring raw material vibration disk 3, a spring raw material feeding rail 31 matched with a spring raw material vibration disk 33, and a base jacking assembly 32 butted with the spring raw material feeding rail 31 and used for jacking up the spring for feeding;

as shown in fig. 7, in this embodiment, the spring jacking assembly 32 includes a supporting seat 321 for spring jacking, a supporting frame 322 for spring jacking disposed on the supporting seat 321 for spring jacking, a cylinder 323 for spring jacking disposed on the supporting frame 322 for spring jacking, and a spring jacking seat 324 disposed at an output end of the cylinder for spring jacking and used for jacking the spring, the spring jacking seat 324 is provided with a jacking pin 325 matched with the spring, and a tail end of the jacking pin 325 is provided with a conical surface (not identified in the figure);

as shown in fig. 7, in the present embodiment, the spring mounting station 3 includes a XY-axis sliding table 35 for mounting a spring, a clamp cylinder 36 for mounting a spring provided in the X-axis direction of the XY-axis sliding table 35 for mounting a spring, a clamp 37 for mounting a spring provided on the clamp cylinder 36 for mounting a spring, and a spring guide assembly 38 provided below the main support plate 10;

as shown in fig. 7, in the present embodiment, the spring guide assembly 38 includes a spring guide support plate 381 disposed below the main support plate 10, a spring guide clamp cylinder 382 disposed on the spring guide support plate 381, and a spring guide clamp 383 disposed at an output end of the spring guide clamp cylinder, wherein the spring guide clamp 383 performs a guide function on a spring to be installed, so that the spring is not inclined;

as shown in fig. 7, in this embodiment, a spring presence/absence detection station 34 is further disposed on the platform 11; the spring presence/absence detecting station 34 includes a spring presence/absence detecting connection plate 341 provided below the main support plate 10, and a spring presence/absence detecting CDD detecting lens 342 provided on the spring presence/absence detecting connection plate 341, and the spring presence/absence detecting CDD detecting lens 342 is aligned to the feeding tool holder 90.

As shown in fig. 2, in this embodiment, the end of the ferrule to be installed is provided with a protective sleeve, and the protective sleeve needs to be removed during installation, and only the ferrule is installed; the ferrule feeding mechanism (not marked in the figure) comprises a T-shaped support rod 40 arranged on the platform 11, an XY-axis sliding table 401 for ferrules arranged on the T-shaped support rod 40, an L-shaped connecting block 402 for ferrules arranged on the XY-axis sliding table 401 in the X-axis direction, an air nozzle 404 for ferrules arranged in the L-shaped connecting block 402 for ferrules and used for adsorbing the ferrules, a first vacuum emitter 403 connected to the rear part of the air nozzle 404 for ferrules, and a feeding table 41 for ferrules arranged on one side of a turntable assembly (not marked in the figure) for ferrules;

as shown in fig. 2, in the present embodiment, the ferrule rotary table assembly (not shown) includes a ferrule rotary table 43, sixteen ferrule tools 44 uniformly distributed in the ferrule rotary table 43 for fixing the ferrules, wherein a second vacuum emitter 45 for adsorbing the ferrules is disposed at the bottom of the ferrule tools 44;

as shown in fig. 2, in the present embodiment, the ferrule support plate 42 is provided in a fixed end on the ferrule indexing mechanism 47 via a ferrule-use elevation fixing block 46, which can be held stationary on the ferrule-use indexing mechanism 47;

as shown in fig. 2, in the present embodiment, the core insert indexing mechanism 47 is a sixteen-index divider that performs a rotary indexing operation by being driven by a core insert reducer (not shown);

as shown in fig. 2, in this embodiment, the collection assembly 48 for collecting the ferrule protection sleeve includes an XY axis sliding table 481 for collecting the ferrule protection sleeve, a clamping cylinder 482 for collecting the ferrule protection sleeve disposed in the X axis direction of the XY axis sliding table 481 for collecting the ferrule protection sleeve, and a clamp 483 disposed at an output end of the clamping cylinder for collecting the ferrule protection sleeve and used for clamping the protection sleeve.

As shown in fig. 8, 9 and 10, in the present embodiment, the ferrule mounting station 4 includes a ferrule mounting XY-axis slide table 401, a ferrule mounting clamp cylinder 402 disposed in the X-axis direction of the ferrule mounting XY-axis slide table 401, a ferrule mounting clamp 403 disposed on the ferrule mounting clamp cylinder 402, and a ferrule guide assembly (not shown) disposed below the main support plate 10;

as shown in fig. 8, 9 and 10, in the present embodiment, the ferrule guide assembly (not shown) includes a ferrule guide support plate 404 disposed below the main support plate 10, a ferrule guide clamp cylinder 405 disposed on the ferrule guide support plate 404, and a ferrule guide clamp 406 disposed at an output end of the ferrule guide clamp cylinder;

as shown in fig. 8, 9 and 10, in the present embodiment, a ferrule adjusting station 49 and a ferrule holding assembly (not shown) are further disposed on the platform 11;

as shown in fig. 8, 9 and 10, in the present embodiment, the ferrule adjusting station 49 includes a ferrule adjusting cylinder 491, a ferrule adjusting connecting plate 492 provided at an output end of the ferrule adjusting cylinder, and a ferrule adjusting block 493 provided at the ferrule adjusting connecting plate 492, and the ferrule adjusting block 493 is provided with an adjusting inclined surface 494 for adjusting a position of the ferrule;

as shown in fig. 8, 9 and 10, in the present embodiment, the ferrule holding assembly (not shown) includes a ferrule holding support 407, a ferrule holding clamp cylinder 408 provided on the ferrule holding support 407, and a ferrule holding clamp 409 provided on an output end of the ferrule holding clamp cylinder.

As shown in fig. 11 and 12, in this embodiment, the shell feeding assembly 50 includes a shell raw material vibrating disk 53, a shell raw material feeding rail 51 matched with the shell raw material vibrating disk 53, and a pushing assembly 52 for pushing a shell on the shell raw material feeding rail 51, where the pushing assembly 52 includes a supporting seat 521 for pushing, a material channel 522 arranged on the supporting seat 521 for pushing, and a pushing cylinder 523 arranged on the material channel 522 for pushing, and the pushing cylinder 523 abuts against the shell through a pushing plate 524;

as shown in fig. 11 and 12, in the present embodiment, the housing mounting station 5 includes a housing mounting XY-axis slide table 501, a housing mounting clamp cylinder 502 provided in the X-axis direction of the housing mounting XY-axis slide table 501, and a ferrule mounting jig 503 provided on the housing mounting clamp cylinder 502;

as shown in fig. 11 and 12, in the present embodiment, a shell compacting station 54 and a shell in-position detecting station 55 for installing the shell in position are further provided on the platform 11;

as shown in fig. 11 and 12, in this embodiment, the shell compactor 54 includes a shell compactor assembly 56 disposed above the main support plate 11, a shell guide assembly 57 disposed below the main support plate 11,

as shown in fig. 11 and 12, in the present embodiment, the housing compacting assembly 56 includes a housing compacting connecting plate 561 disposed above the main supporting plate 11, a housing compacting cylinder 52 disposed at an end of the housing compacting connecting plate 561, and a housing compacting rod 563 disposed at an output end of the housing compacting cylinder, wherein the housing compacting rod 563 is hollow at an axial center;

as shown in fig. 11 and 12, in the present embodiment, the housing aligning member 57 includes a housing aligning support plate 571 disposed below the main support plate 11, a housing aligning clamp cylinder 572 disposed on the housing aligning support plate 571, and a housing aligning jig 573 disposed at an output end of the housing aligning clamp cylinder;

as shown in fig. 11 and 12, in the present embodiment, the housing in-position detecting station 55 includes a housing in-position detecting mounting base 551 disposed above the main supporting plate 11, a housing in-position detecting cylinder 552 disposed in the housing in-position detecting mounting base 551, a housing in-position detecting connecting plate 553 disposed at an output end of the housing in-position detecting cylinder, a housing in-position detecting head 554 disposed in the housing in-position detecting connecting plate 553, the housing in-position detecting head 554 being aligned with the feeding tool holder, a housing in-position detecting connecting auxiliary plate 555 further disposed at the other end of the housing in-position detecting cylinder 552, a detecting sensing block 556 corresponding to the housing in-position detecting head 554 being disposed on the housing in-position detecting auxiliary plate 555,

if the shell is in place, the detection head 554 for detecting the shell in place can not penetrate through the shell to irradiate the sensing block 556 for detecting, and at this time, the installation mode is qualified;

if the sensor block 556 receives a signal from the sensor head 554 for detecting the cover in place, it indicates that the cover is not compacted in place, which indicates that the product has a problem and needs to be stopped for detection.

As shown in fig. 13 and 14, in this embodiment, an elastic force detection station 6 is further disposed on the platform 11; the elastic force detection station 6 comprises an elastic force detection assembly 61 and an elastic force detection guide clamp 62;

the elasticity detection assembly 61 comprises an elasticity detection mounting seat 612 arranged above the main supporting plate 11, an elasticity detection cylinder 613 arranged on the elasticity detection mounting seat 612, an elasticity detection connecting plate 614 arranged at the output end of the elasticity detection cylinder, and an elasticity detection head 615 arranged in the elasticity detection connecting plate 614, wherein the elasticity detection head 615 is positioned right above the loading tool clamp 90;

the elasticity detection guide clamp 62 comprises an elasticity detection guide support plate 621 arranged below the main support plate 11, an elasticity detection guide clamping cylinder 622 arranged on the elasticity detection guide support plate 621, and an elasticity detection guide clamp 623 arranged at the output end of the elasticity detection guide clamping cylinder, wherein the elasticity detection guide clamp 623 can effectively guide the workpiece of the feeding tool clamp 90.

As shown in fig. 15, in this embodiment, the dust cap feeding assembly 70 includes a dust cap raw material vibration disk 73, a dust cap raw material feeding rail 71 matched with the dust cap raw material vibration disk 73, and a dust cap jacking assembly 72 butted with the dust cap raw material feeding rail 71 and used for jacking up the dust cap for feeding;

the dustproof cap jacking assembly 72 comprises a supporting seat 721 for jacking the dustproof cap, a supporting frame 722 for jacking the dustproof cap arranged on the supporting seat 721 for jacking the dustproof cap, a cylinder 723 for jacking the dustproof cap arranged on the supporting frame 722 for jacking the dustproof cap, and a dustproof cap jacking seat 724 arranged at the output end of the cylinder for jacking the dustproof cap and used for jacking the dustproof cap;

the dust cap mounting station 7 comprises an XY-axis sliding table 701 for mounting the dust cap, a clamping cylinder 702 for mounting the dust cap, a clamp 703 for mounting the dust cap, and a dust cap guiding assembly 74, wherein the clamping cylinder 702 is arranged in the X-axis direction of the XY-axis sliding table 701 for mounting the dust cap, the clamp 703 is arranged on the clamping cylinder 702 for mounting the dust cap, and the dust cap guiding assembly 74 is arranged below the main supporting plate 11;

the dust cap guiding assembly 74 comprises a dust cap guiding support plate 741 arranged below the main support plate 11, a dust cap guiding clamp cylinder 742 arranged below the dust cap guiding support plate 741, and a dust cap guiding clamp 743 arranged at an output end of the dust cap guiding clamp cylinder;

the platform 11 is further provided with a dust cap compacting station 75.

The dust cap compacting station 75 comprises a dust cap compacting assembly 76 arranged above the main supporting plate 11, a dust cap guiding assembly 77 arranged below the main supporting plate 11,

the dust cap compacting assembly 76 comprises a dust cap compacting connecting plate 761 arranged above the main supporting plate 11, a dust cap compacting cylinder 762 arranged at the tail end of the dust cap compacting connecting plate 761, and a dust cap compacting rod 763 arranged at the output end of the dust cap compacting cylinder;

the dust cap guiding assembly 77 comprises a dust cap guiding support plate 771 arranged below the main support plate 11, a dust cap guiding clamping cylinder 772 arranged on the dust cap guiding support plate 771, and a dust cap guiding clamp 773 arranged at the output end of the dust cap guiding clamping cylinder;

as shown in fig. 1, 16 and 17, in the present embodiment, the finished product blanking station 8 includes a T-shaped support rod 81 for blanking disposed on the platform 11, an XY-axis sliding table 82 for blanking disposed on the T-shaped support rod 81 for blanking, an L-shaped connection block 83 for blanking disposed in the X-axis direction of the XY-axis sliding table 82 for blanking, a clamping cylinder 84 for blanking disposed on the L-shaped connection block 83 for blanking, a clamp 85 for blanking disposed on the clamping cylinder 84 for blanking, and a finished product blanking transport table 802 disposed on the main turntable assembly side;

finished product unloading subassembly 80 includes finished product unloading conveying platform 802, sets up finished product layer board 801 at unloading conveying platform 802.

The embodiments of the present invention are preferred embodiments of the present invention, and the scope of the present invention is not limited by these embodiments, so: all equivalent changes made according to the structure, shape and principle of the invention are covered by the protection scope of the invention.

Claims

1. An optical fiber interface assembly detection device comprises a rack and a platform arranged on the rack;

the method is characterized in that: the ferrule feeding assembly comprises a ferrule rotary disc assembly and a ferrule feeding mechanism in butt joint fit with the ferrule rotary disc assembly;

2. A fiber optic interface assembly inspection device according to claim 1, wherein: the main turntable assembly comprises a main turntable and sixteen feeding tool clamps which are uniformly distributed in the main turntable;

3. A fiber optic interface assembly testing device according to claim 2, wherein: the ferrule feeding mechanism comprises a T-shaped support rod arranged on the platform, an XY-axis sliding table for ferrules arranged on the T-shaped support rod, an L-shaped connecting block for ferrules arranged on the XY-axis sliding table in the X-axis direction, an air nozzle for ferrules arranged in the L-shaped connecting block for ferrules and used for adsorbing the ferrules, a first vacuum emitter connected to the rear part of the air nozzle for ferrules, and a feeding table for ferrules arranged on one side of the turntable assembly for ferrules;

4. A fiber optic interface assembly testing device according to claim 3, wherein:

the base feeding assembly comprises a base raw material vibrating disc, a base raw material feeding rail matched with the base raw material vibrating disc, and a base jacking assembly which is butted with the base raw material feeding rail and used for jacking the base for feeding;

5. A fiber optic interface assembly testing device according to claim 2, wherein:

the spring feeding assembly comprises a spring raw material vibrating disk, a spring raw material feeding rail matched with the spring raw material vibrating disk, and a base jacking assembly which is butted with the spring raw material feeding rail and used for jacking the spring for feeding;

6. A fiber optic interface assembly testing device according to claim 3, wherein:

the core insert mounting station comprises an XY axial sliding table for mounting the core insert, a clamping cylinder for mounting the core insert arranged in the X-axis direction of the XY axial sliding table for mounting the core insert, a clamp for mounting the core insert arranged on the clamping cylinder for mounting the core insert, and a core insert guiding assembly arranged below the main supporting plate;

7. A fiber optic interface assembly testing device according to claim 2, wherein:

the shell feeding assembly comprises a shell raw material vibrating disc, a shell raw material feeding rail matched with the shell raw material vibrating disc and a pushing assembly used for pushing a shell on the shell raw material feeding rail, wherein the pushing assembly comprises a supporting seat for pushing, a material channel for pushing arranged on the supporting seat for pushing and a pushing cylinder arranged on the material channel for pushing, and the pushing cylinder is abutted to the shell through a pushing plate;

the platform is also provided with a shell compacting station and a shell in-place detection station, wherein the shell compacting station and the shell in-place detection station are used for installing the shell in place; the shell compacting station comprises a shell compacting component arranged above the main supporting plate and a shell guide component arranged below the main supporting plate,

8. A fiber optic interface assembly testing device according to claim 2, wherein: an elastic detection station is also arranged on the platform; the elasticity detection station comprises an elasticity detection assembly and a guide clamp for elasticity detection;

9. A fiber optic interface assembly testing device according to claim 2, wherein:

the dustproof cap feeding assembly comprises a dustproof cap raw material vibrating disk, a dustproof cap raw material feeding track matched with the dustproof cap raw material vibrating disk, and a dustproof cap jacking assembly which is in butt joint with the dustproof cap raw material feeding track and used for jacking the dustproof cap for feeding;

a dust cap compacting station is also arranged on the platform; the dust cap compacting station comprises a dust cap compacting component arranged above the main support plate and a dust cap guiding component arranged below the main support plate,

the dust cap guide assembly comprises a support plate for guiding the dust cap below the main support plate, a clamping cylinder for guiding the dust cap arranged on the support plate for guiding the dust cap, and a dust cap guide clamp arranged at the output end of the clamping cylinder for guiding the dust cap.

10. A fiber optic interface assembly inspection device according to claim 1, wherein: the finished product blanking station comprises a T-shaped support rod arranged on the platform, a XY-axis sliding table for blanking arranged on the T-shaped support rod for blanking, an L-shaped connecting block arranged in the X-axis direction of the XY-axis sliding table for blanking, a clamping cylinder for blanking arranged on the L-shaped connecting block for blanking, a clamp for blanking arranged on the clamping cylinder for blanking and a finished product blanking transport table arranged on one side of the main turntable assembly; the finished product blanking assembly comprises a finished product blanking transport platform and a finished product supporting plate arranged on the blanking transport platform.