CN214225480U - Linkage type optical fiber peeling and cleaning equipment - Google Patents

Abstract

The utility model discloses a linkage type optical fiber skinning, cleaning device, including the main bottom plate, set firmly the optic fibre fixture who is used for a fixed optic fibre end of centre gripping on the main bottom plate, locate the moving platform subassembly on the main bottom plate, still including setting firmly on moving platform in proper order and being on a parallel with optic fibre fixture's clean subassembly and the hot subassembly of skinning, still include with clean subassembly and the hot subassembly of skinning be connected the linkage translation subassembly in order to carry out the hot simultaneously skin and clean centre gripping to the optic fibre, then by the clean subassembly of moving platform control system drive and the hot subassembly of skinning remove with another end of optic fibre in order to carry out the hot skin and clean along with moving platform. The equipment finishes peeling and cleaning of the optical fiber at one time, is quick and automatic to operate, an operator only needs to lay the optical fiber to be processed, and the equipment has the advantages of high efficiency, automation, no pollution, high processing qualification rate and the like in use, and has the advantages of being light, small and exquisite, convenient to carry, low in failure rate, low in cost and the like in structure.

Description

Linkage type optical fiber peeling and cleaning equipment

Technical Field

The utility model relates to an optical fiber processing technology field, concretely relates to linkage type optical fiber peeling and cleaning equipment.

Background

The existing full-automatic optical fiber processing integrated machine on the market is APM-101 of Japan rattan storehouse company, and the equipment has the defects of high price, large size and structure, heavy weight, inconvenience in carrying, complex mechanism and the like on the market.

The optical fiber stripper on the domestic market mainly takes an inclined-opening wire stripper as a main part, an optical fiber outer-layer tube is stripped through manual operation, the optical fiber is clamped by the manually operated wire stripper, the optical fiber outer-layer tube is manually and lightly cut and kept stable, then the outer-layer tube is stripped through pulling backwards, so that the optical fiber core is cut or the optical fiber is cut through careless operation, the strict requirements on the manual operation proficiency and the wire stripping strength are met, and the optical fiber stripper is very difficult to master.

The materials for cleaning the optical fiber manually, such as the optical fiber cleaning cotton and the optical fiber cleaning paper, wipe off the residual dregs of the optical fiber outer tube remaining on the stripped optical fiber core wire, but the manual wiping is needed, and the manual force is also needed to be kept. This makes it difficult for the operator to break the optical fiber and strain it.

In view of the above technical problems, the present inventors have made extensive studies and have devised the present invention.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the application provides a linkage type optical fiber peeling and cleaning device, peeling, cleaning and one-time completion of optical fibers are achieved, automatic operation is fast, an operator only needs to place optical fibers to be processed, and the device has the advantages of being efficient, automatic, free of pollution, high in processing qualification rate and the like in use, and has the advantages of being light, small, convenient to carry, low in failure rate, low in cost and the like in structure.

In order to achieve the purpose, the following technical scheme is adopted:

a linkage type optical fiber peeling and cleaning device comprises a main bottom plate, an optical fiber clamping mechanism fixedly arranged on the main bottom plate and used for clamping and fixing one end of an optical fiber, a moving platform assembly arranged on the main bottom plate, a cleaning assembly, a hot peeling control system, a cleaning control system and a moving platform control system, wherein the moving platform assembly comprises a moving platform and a moving platform translation driving assembly, the cleaning assembly and the hot peeling assembly are sequentially fixedly arranged on the moving platform and are parallel to the optical fiber clamping mechanism; the optical fiber clamping mechanism, the cleaning assembly and the hot peeling assembly are respectively provided with an optical fiber placing station which is positioned on a straight line; the device comprises a movable platform control system, a movable platform control system and a thermal peeling assembly, wherein the movable platform control system is used for driving the movable platform control system to move along with the movable platform so as to perform thermal peeling and cleaning on the other end of the optical fiber.

Further, clean subassembly is including being fixed in left fixing base on the moving platform and through the clean seat of right side removal of translation about the linkage translation subassembly, left side fixing base with be provided with clean sponge on the relative terminal surface of the clean seat of right side removal, clean control system drive right side remove clean seat and be close to with the centre gripping optic fibre left the clean subassembly is in order to clean along optic fibre lateral shifting under moving platform's drive the optic fibre that the subassembly of skinning of heat was skinned and is skinned the completion is optic fibre.

Furthermore, the hot peeling assembly comprises a supporting vertical plate fixed on the moving platform, a left pressure head fixedly arranged on the left side of the supporting vertical plate, and a right pressure head arranged on the right side of the supporting vertical plate and capable of transversely translating through the translation guide assembly, wherein the side parts of the left pressure head and the right pressure head are oppositely provided with a left peeling head and a right peeling head, heating pipes are arranged in the left pressure head and the right pressure head, and the hot peeling assembly also comprises a thermocouple arranged in the left pressure head; the right side pressure head links to each other with the right pressure head direction slider upper end of translation direction subassembly, the lower part of right side pressure head direction slider sets up elastic connection subassembly, elastic connection subassembly compresses tightly the slider including setting firmly the direction subassembly on moving platform, the elasticity of being connected with the direction subassembly sliding block, elasticity compresses tightly the lower extreme that the slider passes through the second spring guide pole and connects right pressure head direction slider, elasticity compresses tightly the slider and connects linkage translation subassembly to drive through linkage translation subassembly elasticity right side pressure head to left side pressure head is close to with the centre gripping and the skin is shelled to heat optic fibre.

Further, the linkage translation assembly comprises a linkage screw rod motor, a first connecting block and a second connecting block, the first connecting block and the second connecting block are arranged at the driving end of the linkage screw rod motor, the first connecting block is connected with the right movable cleaning seat, and the second connecting block is connected with the elastic pressing sliding block.

Furthermore, the optical fiber clamping mechanism comprises a support frame, a transverse support plate arranged on the support frame and a cover plate with one end hinged to the transverse support plate, a silica gel pad is arranged at the position where the cover plate and the transverse support plate are overlapped up and down, magnet blocks are arranged on the lower end face of the cover plate and the upper end face of the transverse support plate oppositely, and an optical fiber placing station is arranged at the position where the cover plate and the transverse support plate are overlapped up and down.

Drawings

Fig. 1 is a schematic structural view of a full-automatic optical fiber peeling, cleaning and cutting integrated machine of the present invention;

FIG. 2 is a partially omitted schematic structural view of the fully automatic optical fiber stripping, cleaning and cutting integrated machine of the present invention;

fig. 3 is a schematic structural diagram of the mobile platform assembly of the present invention;

fig. 4 is a schematic view of the fully automatic optical fiber stripping, cleaning and cutting machine according to the present invention, with a structure omitted from another part;

FIG. 5 is a schematic structural view of the optical fiber clamping mechanism of the present invention;

fig. 6 is a schematic structural view of the cutting assembly of the present invention;

FIG. 7 is an enlarged view of the structure at A in FIG. 6;

FIG. 8 is an enlarged view of the structure at B in FIG. 6;

FIG. 9 is an enlarged view of the structure of FIG. 6 at C;

FIG. 10 is an enlarged view of the structure of FIG. 6 at D;

fig. 11 is a schematic structural view of the cutting assembly of the present invention from another angle;

FIG. 12 is an enlarged view of the structure at E in FIG. 11;

fig. 13 is a schematic structural view of the cleaning assembly of the present invention;

FIG. 14 is a schematic view of the cleaning assembly and the thermal peeling assembly of the present invention;

FIG. 15 is a schematic structural view of a thermal peeling assembly of the present invention;

in the figure: a main bottom plate-10; a drawer type blanking box-11; an optical fiber clamping mechanism-20; a support frame-21; a transverse support plate-22; a cover plate-23; a silica gel pad-24; a magnet block-25; -a mobile platform assembly-30; a mobile platform-31; -a mobile platform translation drive assembly-32; a first lead screw stepper motor-321; a first feed screw nut-323; a first lead screw nut mounting block-324; a first guide-325; a first slider-326; a slider pad-327; -a severing assembly-40; cutting off the main frame-41; cutting the support frame-411; pressing down the optical fiber gasket-4111; a vertical lift assembly-42; the vertical sliding plate-421, the vertical sliding plate lifting driving component-422, the second lead screw stepping motor-4221, the second lead screw nut-4222 and the second lead screw nut mounting block-4223; a vertical sliding panel elevation guide assembly-423; a second guide rail-4231; a horizontal movement assembly-43; a horizontal sliding plate-431; a horizontal slide plate translation drive assembly-432; a third lead screw stepping motor-4321; a third feed screw nut-4322; a third feed screw nut mounting block-4323; a horizontal sliding plate translation guide assembly-433; third guide rail-4331; a resilient clamp assembly-44; a top end cap-441; press polish the fiber mat-4411; a biasing assembly-442; guide sleeve-4421; fiber presser foot seat-4422; spring press-4423; -45, an elastic cutting assembly; an elastic block-451; a first spring guide-452; a first compression spring-4521; a first spring pad-4522; a second spring pad-4523; an optical fiber cutter-453; a cutting drive-454; an electromagnetic push rod-4541; a cleaning assembly-50; a left fixed seat-51; a right mobile cleaning base-52; a cleaning sponge-53; hot peeling assembly-60; a supporting vertical plate-61; a left ram-62; a translational guide assembly-63; a right ram guide slide-631; a right ram-64; left peeling head-65; a right stripper head-66; heating a tube-67; thermocouple-68; a resilient connecting member-69; a guide assembly-691; elastically pressing the slider-692; linkage translation assembly-70; linkage screw motor-71; a first connecting block-72; a second connecting block-73.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings and specific embodiments.

Referring to fig. 1-15, the present invention provides a full-automatic optical fiber peeling, cleaning and cutting integrated machine, which comprises a main base plate 10 and a housing assembly, an optical fiber clamping mechanism 20 fixed on the main base plate 10 for clamping and fixing an end of an optical fiber, a moving platform assembly 30 arranged on the main base plate 10, the moving platform assembly 30 comprises a moving platform 31 and a moving platform translation driving assembly 32, the moving platform translation driving assembly 32 comprises a first lead screw stepping motor 321 and a first lead screw nut 323, the first lead screw nut mounting block 324, the first guide rail 325, the first sliding block 326 and the sliding block cushion block 327, wherein the first sliding block 326 is connected with the mobile platform through the sliding block cushion block 327, the first lead screw stepping motor 321 drives the first lead screw nut 323 to reciprocate along a lead screw so as to drive the first lead screw nut mounting block 324 connected with the first lead screw nut 323 to reciprocate, and therefore the translation motion of the mobile platform is realized; the device also comprises a cutting component 40, a cleaning component 50 and a hot peeling component 60 which are sequentially and fixedly arranged on the moving platform 31 and are parallel to the optical fiber clamping mechanism 20, and a hot peeling control system, a cutting control system, a cleaning control system and a moving platform control system which are correspondingly arranged; the optical fiber clamping mechanism 20, the cutting assembly 40, the cleaning assembly 50 and the hot peeling assembly 60 are respectively provided with optical fiber placing stations which are positioned on a straight line; still include the linkage translation subassembly 70 that is connected with clean subassembly 50 and hot subassembly 60 of skinning in order to carry out the while heat to the optic fibre and skin and clean the centre gripping, then by the clean subassembly 50 of moving platform control system drive and hot subassembly 60 of skinning along with the moving platform removes in order to carry out the heat to another end of optic fibre and skin and clean, another end of optic fibre is cut off by cutting off control system control cutting off subassembly 40 at last, the skinning to an optic fibre has been accomplished promptly, a series of operations clean and cut off, only need to put into the optic fibre manual work can accomplish fast, high efficiency, the degree of automation is high, and the outward appearance and the quality of optic fibre have been guaranteed. In this embodiment, as shown in fig. 6 to 12, the cutting assembly 40 includes a cutting main frame 41, a vertical lifting assembly 42, a horizontal moving assembly 43, an elastic clamping assembly 44, and an elastic cutting assembly 45, the bottom of which is fixedly connected to the moving platform 31, the vertical lifting assembly 42 is fixedly disposed on one side portion of the cutting main frame 41, the vertical lifting assembly 42 includes a vertical sliding plate 421, a vertical sliding plate lifting driving assembly 422, and a vertical sliding plate lifting guiding assembly 423, the vertical sliding plate 421 is connected to one side portion of the cutting main frame 41 through the vertical sliding plate lifting guiding assembly 423, and the vertical sliding plate lifting driving assembly 422 drives the vertical sliding plate 421 to lift along the cutting main frame 41, specifically, the vertical sliding plate lifting driving assembly 422 includes a second lead screw stepping motor 4221, a second lead screw nut 4222, and a second lead screw nut mounting block 4223, the vertical sliding plate lifting guiding assembly 423 is a second guide rail 4231 fixed to the cutting main frame 41, the second lead screw nut mounting block 4223 is connected to the vertical sliding plate 421, and thus when the second lead screw stepping motor 4221 drives the second lead screw nut mounting block 4223 connected to the second lead screw nut 4222 to reciprocate along the second guide rail 4231, the vertical sliding plate 421 is further caused to reciprocate up and down along the cut main frame 41; the horizontal moving assembly 43 comprises a horizontal sliding plate 431 disposed on the vertical sliding plate 421, a horizontal sliding plate translation driving assembly 432, and a horizontal sliding plate translation guiding assembly 433, wherein the horizontal sliding plate 431 is connected to the vertical sliding plate 421 through the horizontal sliding plate translation guiding assembly 433, and the horizontal sliding plate 431 is driven by the horizontal sliding plate 431 translation driving assembly to move horizontally along the vertical sliding plate 421, specifically, the horizontal sliding plate translation driving assembly 432 comprises a third lead screw stepping motor 4321, a third lead screw nut 4322, and a third lead screw nut mounting block 4323 fixed on the vertical sliding plate 421, the third lead screw nut mounting block 4323 is connected to the horizontal sliding plate 431, the horizontal sliding plate translation guiding assembly 433 is a third guide rail 4331 fixed on the vertical sliding plate 421, so that when the third lead screw stepping motor 4321 drives the third lead screw nut mounting block 4323 connected to the third lead screw nut 4322 to reciprocate along the third guide rail 4331, further causing the horizontal sliding plate 431 to move in translation along the vertical sliding plate 421; the elastic clamping assembly 44 comprises a top end cover 441 arranged at the end part of the horizontal sliding plate 431, a pressing assembly 442 arranged on the top end cover 441, and a cutting support frame 411 arranged on the cutting main frame 41, wherein the upper end surface of the cutting support frame 411 is provided with an optical fiber placing station, the pressing assembly 442 comprises a guide sleeve 4421 arranged in the top end cover 441, an optical fiber presser foot seat 4422 arranged at the bottom of the guide sleeve 4421, a spring pressing block 4423 arranged at the top of the guide sleeve 4421, and a compression spring arranged between the guide sleeve 4421 and the spring pressing block 4423; a group of downward pressing optical fiber gaskets 4111 are symmetrically arranged at an optical fiber placing station on the upper end surface of the cutting support frame 411, a group of upward pressing optical fiber gaskets 4411 are also symmetrically arranged at an optical fiber placing station on the lower end surface of the top end cover 441 corresponding to the upper end surface of the cutting support frame 411, the cutting control system controls the vertical lifting component 42 and the horizontal moving component 43 to drive the upward pressing optical fiber gasket 4411 of the top end cover 441 of the elastic clamping component 44 to be overlapped with the downward pressing optical fiber gasket 4111 on the upper end surface of the cutting support frame 411 so as to press the stripped optical fiber, and the optical fiber presser foot seat 4422 is arranged between the group of upward pressing optical fiber gaskets 4411, so that the bottom of the optical fiber presser foot seat 4422 contacts and elastically presses the optical fiber; the elastic cutting assembly 45 comprises a cutting support frame 411 arranged on the cutting main frame 41, an elastic stop block 451 with one side part slidably connected with the cutting main frame 41, a first spring guide rod 452 transversely arranged on the cutting support frame 411, the other side part of the elastic stop block 451 is sleeved on the first spring guide rod 452, specifically, a first compression spring 4521 is sleeved on the first spring guide rod 452, the elastic cutting assembly further comprises a first spring cushion 4522 and a second spring cushion 4523 which are sleeved on the first spring guide rod 452 and located at the front end part and the rear end part of the elastic stop block 451, an optical fiber cutting knife 453 is fixedly arranged on the elastic stop block 452, the elastic cutting assembly further comprises a cutting driving piece 454 which drives the elastic stop block 452 to horizontally move along the first spring guide rod 452 and the sliding assembly of the cutting main frame 41, and the optical fiber cutting driving piece 453 is driven to elastically cut the optical fiber located at the optical fiber placing station on the upper end surface of the cutting support frame 411.

In this embodiment, as shown in fig. 6, 8, 11, and 12, the cutting driving component 454 is an electromagnetic push rod 4541, after an electromagnet of the electromagnetic push rod 4541 is powered on, the electromagnetic push rod 4541 pushes the spring stopper 452 to drive the optical fiber cutting blade 453 to cut the optical fiber fixed on the elastic clamping component 44, and after the electromagnetic push rod is powered off, the electromagnetic push rod moves outwards under the action of the first compression spring 4521 to wait for the next pushing and cutting action; the optical fiber presser foot seat 4422 is arranged between a group of upper press polish spacers 4411, and when the optical fiber is cut, the optical fiber presser foot seat 4422 and the optical fiber cutter 453 vertically correspond to each other to enable the optical fiber to be attached to the optical fiber presser foot seat 4422 and the optical fiber cutter 453, so that the cutting efficiency and the cutting quality of the optical fiber are facilitated; when the electromagnet of the electromagnetic push rod 4541 is powered off, the electromagnet is reset to an original state under the action of the first compression spring to prepare for next cutting action; this cutting driving piece 454 adopts the electromagnetism push rod, compares the cylinder drive, and is light and handy, conveniently carries, and does not receive the restriction that the cylinder needs the air supply, to the condition of the no air supply of formula that flows optic fibre construction operation under, has made things convenient for workman's work greatly.

In this embodiment, as shown in fig. 13, the cleaning assembly 50 includes a left fixing seat 51 fixed on the moving platform 31 and a right moving cleaning seat 52 moving left and right through a linkage moving assembly 70, cleaning sponges 53 are disposed on the opposite end faces of the left fixing seat 51 and the right moving cleaning seat 52, the cleaning control system drives the right moving cleaning seat 52 to approach the left fixing seat 51 to clamp the optical fiber, and the cleaning assembly 50 moves laterally along the optical fiber under the driving of the moving platform 31 to clean the optical fiber stripped by the thermal stripping assembly 60. In this embodiment, as shown in fig. 13 and 14, the thermal peeling assembly 60 includes a supporting vertical plate 61 fixed on the moving platform 31, a left pressure head 62 fixedly disposed on the left side of the supporting vertical plate 61, and a right pressure head 64 disposed on the right side of the supporting vertical plate 61 and capable of transversely translating through a translation guide assembly 63, wherein a left peeling head 65 and a right peeling head 66 are disposed on the side portions of the left pressure head 62 and the right pressure head 64, a heating pipe 67 is disposed in the left pressure head 62 and the right pressure head 64, and a thermocouple 68 disposed in the left pressure head; the right pressure head 64 is connected with the upper end part of a right pressure head guide sliding block 631 of the translation guide assembly 63, the lower part of the right pressure head guide sliding block 631 is provided with an elastic connection assembly 69, the elastic connection assembly 69 comprises a guide assembly 691 fixedly arranged on the mobile platform 31 and an elastic pressing sliding block 692 connected with the guide assembly sliding block, the elastic pressing sliding block 692 is connected with the lower end of the right pressure head guide sliding block 631 through a second spring guide rod 693, the elastic pressing sliding block 692 is connected with a linkage translation assembly 70, and the right pressure head 64 is elastically driven to be close to the left pressure head 62 through the linkage translation assembly 70 so as to clamp and thermally peel the optical fiber. The linkage translation assembly 70 comprises a linkage screw rod motor 71, a first connecting block 72 and a second connecting block 73, wherein the first connecting block 72 and the second connecting block 73 are arranged at the driving end of the linkage screw rod motor 71, the first connecting block 72 is connected with the right movable cleaning seat 52, and the second connecting block 73 is connected with an elastic pressing sliding block 692. The linkage translation assembly 70 simultaneously drives the cleaning assembly 50 and the thermal peeling assembly 60 to perform thermal peeling and cleaning clamping on the optical fiber, so that after the optical fiber is subjected to thermal peeling, the cleaning clamping assembly 50 and the thermal peeling assembly 60 move along the optical fiber under the action of the moving platform, the peeling and cleaning work on the optical fiber is completed efficiently and high-quality, and preparation is made for subsequent cutting work.

In this embodiment, as shown in fig. 5, the optical fiber clamping mechanism 20 includes a supporting frame 21, a transverse supporting plate 22 disposed on the supporting frame 21, and a cover plate 23 having one end hinged to the transverse supporting plate 22, a silicone pad 24 is disposed at an upper and lower overlapping position of the cover plate 23 and the transverse supporting plate 22, a magnet 25 is disposed on a lower end surface of the cover plate 23 and an upper end surface of the transverse supporting plate 22, and an optical fiber placing station is disposed at an upper and lower overlapping position of the cover plate 23 and the transverse supporting plate 22. The special design of the optical fiber clamping mechanism 20 improves the clamping force on the optical fiber, avoids the damage on the optical fiber, provides a fixed base point for subsequent optical fiber cleaning, optical fiber peeling and optical fiber cutting, and prepares for a series of subsequent work.

In this embodiment, as shown in fig. 2, a drawer type blanking box 11 is provided on the main bottom plate 10 at a position corresponding to the optical fiber cutting position of the optical fiber cutting module directly above, and collects optical fiber waste materials cut by the cutting module and stripped optical fiber sheaths.

By adopting the technical scheme, the specific working process is as follows:

1. and (3) turning on a power supply of the machine, enabling moving parts of the equipment to be in an open position, manually opening the cover plate to enable the optical fibers to penetrate through central slotted holes of all parts, namely the optical fiber placing stations, penetrating into the machine, propping against the parts in the machine until the parts can not stretch into the machine, and manually closing the cover plate.

2. The screw rod motors of the thermal peeling assembly and the cleaning assembly start to act, under the pushing of the screw rod motors, the right pressing head is close to the left pressing head, the right peeling knife slightly cuts into the outer optical fiber tube, the left pressing head and the right pressing head press the optical fiber, and the heating tube starts to heat.

3. The cleaning assembly and the hot peeling assembly move simultaneously, the cleaning seat moving rightwards drives the cleaning sponge to move towards the left fixing seat, and the optical fiber is thoroughly pressed between the left sponge and the right sponge.

4. The optical fiber outer tube is peeled off under the cutting of right peeler, wait to the melting temperature (setting value) of operating panel upper temperature arrival optical fiber outer tube, the optical fiber outer tube begins to melt this moment, the first lead screw step motor of moving platform subassembly begins to move, step motor drive lead screw, make whole platform subassembly all move to equipment inside along optic fibre, inside optical fiber outer tube that is melted is just peeled off along with the moving inwards of platform, the impurity of peeling off the in-process is just taken away by cleaning assembly's clean sponge is whole, clean sponge is just changed for every 100 times of use.

5. The mobile platform stops moving when moving 10-25mm (set according to customer needs), the fixed optical fiber structure of the cutting assembly starts to act from an open state, the horizontal sliding plate horizontally moves under the driving of a screw rod motor of the cutting assembly, and the vertical sliding plate moves from top to bottom after reaching the position, so that the upper pressed optical fiber gasket and the lower pressed optical fiber gasket are overlapped, and the stripped optical fiber inner core is pressed. The electromagnet push rod acts to push the spring stop block to move horizontally inwards, and the cutting blade is driven to cut off the fixed optical fiber inner core. The blade is a tungsten alloy blade, and the hardness and the wear resistance are higher, so that the section of the optical fiber is smooth. Thus, a series of operations of peeling, cleaning the base and cutting off one optical fiber are completed.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention, and any modifications, equivalent replacements, and improvements made within the spirit and principle of the present invention are all included in the protection scope of the present invention.

Claims (5)

1. The linkage type optical fiber peeling and cleaning equipment is characterized by comprising a main bottom plate, an optical fiber clamping mechanism fixedly arranged on the main bottom plate and used for clamping and fixing one end of an optical fiber, a moving platform assembly arranged on the main bottom plate, a cleaning assembly, a hot peeling control system, a cleaning control system and a moving platform control system, wherein the moving platform assembly comprises a moving platform and a moving platform translation driving assembly, the cleaning assembly and the hot peeling assembly are sequentially fixedly arranged on the moving platform and are parallel to the optical fiber clamping mechanism; the optical fiber clamping mechanism, the cleaning assembly and the hot peeling assembly are respectively provided with an optical fiber placing station which is positioned on a straight line; the device comprises a movable platform control system, a movable platform control system and a thermal peeling assembly, wherein the movable platform control system is used for driving the movable platform control system to move along with the movable platform so as to perform thermal peeling and cleaning on the other end of the optical fiber.

2. The linkage type optical fiber peeling and cleaning equipment according to claim 1, wherein the cleaning assembly comprises a left fixing seat fixed on the moving platform and a right moving cleaning seat which moves left and right through the linkage translation assembly, cleaning sponges are arranged on opposite end faces of the left fixing seat and the right moving cleaning seat, a cleaning control system drives the right moving cleaning seat to be close to the left fixing seat to clamp the optical fibers, and the cleaning assembly moves transversely along the optical fibers under the driving of the moving platform to clean the optical fibers peeled by the hot peeling assembly.

3. The linkage type optical fiber peeling and cleaning equipment according to claim 2, wherein the thermal peeling assembly comprises a supporting vertical plate fixed on the moving platform, a left pressure head fixedly arranged on the left side of the supporting vertical plate, a right pressure head arranged on the right side of the supporting vertical plate and capable of transversely translating through a translation guide assembly, a left peeling head and a right peeling head are arranged on the side portions of the left pressure head and the right pressure head oppositely, heating pipes are arranged in the left pressure head and the right pressure head, and the thermal peeling assembly further comprises a thermocouple arranged in the left pressure head; the right side pressure head links to each other with the right pressure head direction slider upper end of translation direction subassembly, the lower part of right side pressure head direction slider sets up elastic connection subassembly, elastic connection subassembly compresses tightly the slider including setting firmly the direction subassembly on moving platform, the elasticity of being connected with the direction subassembly sliding block, elasticity compresses tightly the lower extreme that the slider passes through the second spring guide pole and connects right pressure head direction slider, elasticity compresses tightly the slider and connects linkage translation subassembly to drive through linkage translation subassembly elasticity right side pressure head to left side pressure head is close to with the centre gripping and the skin is shelled to heat optic fibre.

4. The linkage type optical fiber peeling and cleaning device according to claim 3, wherein the linkage translation assembly comprises a linkage lead screw motor, a first connecting block and a second connecting block, the first connecting block and the second connecting block are arranged at the driving end of the linkage lead screw motor, the first connecting block is connected with the right movable cleaning seat, and the second connecting block is connected with the elastic pressing sliding block.

5. The linkage type optical fiber peeling and cleaning equipment according to claim 4, wherein the optical fiber clamping mechanism comprises a support frame, a transverse support plate arranged on the support frame, and a cover plate with one end hinged to the transverse support plate, a silica gel pad is arranged at the position where the cover plate and the transverse support plate are overlapped up and down, magnet blocks are arranged on the lower end face of the cover plate and the upper end face of the transverse support plate in a relative mode, and an optical fiber placing station is arranged at the position where the cover plate and the transverse support plate are overlapped up and down.

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