CN115933059A - Lifting system of optical fiber fusion splicer - Google Patents

Abstract

The invention discloses a lifting system of an optical fiber fusion splicer, which comprises two groups of lifting mechanisms, a boat-shaped body and two groups of clamping components, wherein the lifting mechanisms are oppositely arranged at two sides of the boat-shaped body; when lifting the mechanism and being in the decline position, place optic fibre and press from both sides tightly in clamping part, wherein, be used for the various optic fibre of centre gripping in a set of clamping part, another group clamping part is used for the optic fibre of the outside cover optic fibre protection piece that is equipped with of centre gripping, drives clamping part through drive assembly and carries out the removal of level and vertical direction with optic fibre, makes optic fibre realize whole stable centre gripping at the butt fusion in-process to improve the butt fusion success rate of optic fibre, and effectively reduce the butt fusion and be in the cracked possibility of working process.

Description

Lifting system of optical fiber fusion splicer

Technical Field

The invention relates to the field of hot melting machines, in particular to a lifting system of an optical fiber fusion splicer.

Background

In the construction and maintenance of optical cables in optical communication, an optical fiber fusion splicer is generally required to be used for connecting two optical fibers to form a passage, a coating layer of a fusion spliced part needs to be stripped in the fusion splicing process to enable bare fibers to be fused, the bare fibers are very fine, the fusion spliced part is manually lifted up after fusion splicing, and then a heat shrinkable tube is moved to the fusion spliced part to protect the fusion spliced part, so that the fused bare fibers are very easy to break in the moving process, and fusion splicing failure is caused.

In the publication No. CN209231561U, "the clamping member is fixedly connected to the supporting frame through the base," the clamping member "does not lift along with the lifting mechanism during the lifting process of the" lifting mechanism ", so that after the welding is completed, the" lifting mechanism "lifts the welded bare fiber, which is likely to shake to break the welded portion, resulting in welding failure, and after the welding is completed, the" lifting mechanism "alone cannot horizontally fix the position of the optical fiber, and the deviation between the external heater and the position of the heat shrinkable sleeve can reduce the wrapping performance of the heat shrinkable tube on the welded portion, thereby resulting in easy breakage of the welded portion, making the welded joint unusable, improving the welding cost, and also improving the possibility of breakage of the optical fiber during the use.

Disclosure of Invention

The invention aims to solve the defects in the prior art and provides an elevating system of an optical fiber fusion splicer.

In order to achieve the purpose, the invention adopts the following technical scheme: the lifting mechanism is arranged on two sides of the ship body oppositely, and each lifting mechanism is provided with one group of clamping parts;

the two groups of clamping components respectively clamp one optical fiber;

every group the lifting mechanism contains two sets of drive assembly, every group drive assembly is used for driving respectively the removal of vertical direction or horizontal direction is realized to the hold assembly to realize the butt fusion of optic fibre.

As a further description of the above technical solution: the clamping component is provided with a clamping component cover plate, the clamping component cover plate is movably connected with the clamping component, the two groups of clamping components are respectively a first clamping component and a second clamping component, the first clamping component comprises an optical fiber clamp base for placing optical fibers, and the second clamping component comprises a second clamping clamp base matched with the shape of an optical fiber protection piece.

As a further description of the above technical solution: every group the lifting mechanism still contains base and two sets of tracks, and is two sets of the track all set up in on the base.

As a further description of the above technical solution: the two groups of driving assemblies are respectively a horizontal driving assembly and a vertical driving assembly.

As a further description of the above technical solution: the horizontal driving assembly is connected with the horizontal rail and used for driving the horizontal movement of the clamping component.

As a further description of the above technical solution: the vertical driving assembly is connected with the vertical rail and used for driving the base to move up and down.

As a further description of the above technical solution: the lifting mechanism comprises a first lifting mechanism and a second lifting mechanism.

As a further description of the above technical solution: the first clamping part corresponds to the first lifting mechanism, and the second clamping part corresponds to the second lifting mechanism.

As a further description of the above technical solution: a spring is arranged between the base and the vertical driving component.

As a further description of the above technical solution: when the lifting mechanism is in a descending position, the spring is in an initial state.

The invention has the following beneficial effects:

according to the invention, the optical fiber can be clamped by the clamping component fixedly connected with the lifting mechanism in the process that the lifting mechanism moves up and down, so that the optical fiber is relatively fixed with the lifting mechanism in the horizontal and vertical directions in the moving process, the optical fiber is more stable in the fusion process, the fusion rate of the optical fiber is improved, and the possibility of fracture of the fusion part in the subsequent optical fiber using process is reduced.

Drawings

FIG. 1 is a perspective view of the lifting clamp assembly and boat in a raised position in accordance with the present invention;

FIG. 2 is a perspective view of the lifting/lowering clamp assembly and boat in a lowered position;

FIG. 3 is a perspective view of the first lift mechanism of FIG. 1;

FIG. 4 is a perspective view of the first lifting mechanism of FIG. 1 from another perspective;

FIG. 5 is a perspective view of the second lifting mechanism of FIG. 1;

fig. 6 is a perspective view of the second lifting mechanism of fig. 1.

Illustration of the drawings:

1. a first lifting mechanism; 2. a second lifting mechanism; 3. a boat-shaped body; 4. a first clamping member; 5. a second clamping member; 6. an optical fiber; 11. a first base; 12. a first horizontal rail; 13. a first vertical rail; 14. a first horizontal drive assembly; 15. a first vertical drive assembly; 21. a second base; 22. a second horizontal rail; 23. a second vertical rail; 24. a second horizontal drive assembly; 25. a second vertical drive assembly; 41. an optical fiber clamp base; 42. a first clamping member cover plate; 51. a second clamp fixture base; 52. a second clamping member cover plate; 61. an optical fiber protection member; 62. protecting the jacket; 71. a first spring; 121. a first slider; 122. a first slideway; 131. a second slider; 132. a second slideway; 141. a first horizontal motor; 142. a first horizontal fixing member; 143. a first horizontal pusher; 144. a first threaded sleeve; 145. a first screw; 151. a first vertical motor; 152. a first vertical fixing member; 153. a first vertical pusher; 154. a first turntable; 155. a first bearing.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-6, one embodiment of the present invention is provided: the optical fiber fusion splicing device comprises two groups of lifting mechanisms, a boat-shaped body and two groups of clamping components, wherein the lifting mechanisms are oppositely arranged on two sides of the boat-shaped body, each group of lifting mechanisms is provided with one group of clamping components, the two groups of clamping components respectively clamp one optical fiber, each group of lifting mechanisms comprises two groups of driving components, and each group of driving components is respectively used for driving the clamping components to move in the vertical direction or the horizontal direction so as to realize the fusion splicing of the optical fibers; when the lifting mechanism is located at a descending position, the optical fibers can be placed in the clamping parts to be clamped tightly, wherein one group of clamping parts is used for directly clamping various optical fibers, the other group of clamping parts clamps the optical fibers of which the outer parts are sleeved with the optical fiber protection parts, and the driving assembly of the lifting mechanism drives the clamping parts to move the optical fibers in the horizontal direction and the vertical direction, so that the optical fibers can be stably clamped in the whole process in the fusion process, the fusion success rate of the optical fibers is improved, and the possibility of fracture of the fusion part in the working process can be effectively reduced.

Every group lifts the mechanism and includes base, two sets of tracks and two sets of drive assembly, and wherein, two sets of tracks are horizontal track and vertical track respectively, and two sets of drive assembly are horizontal drive assembly and vertical drive assembly respectively, and track and drive assembly all set up on the base. The horizontal rail is arranged between the clamping component and the base, the horizontal driving component is connected with the clamping component and the base, and the horizontal rail realizes the horizontal movement of the clamping component through the horizontal driving component; the vertical rail is arranged between the base and the vertical driving assembly, and the base is driven by the vertical driving assembly to move up and down, so that the clamping component is lifted up and down. The horizontal track and the vertical track both comprise a sliding rail and a sliding block.

Two sets of mechanisms of lifting contain first lifting mechanism 1 and second lifting mechanism 2, and first lifting mechanism 1 and second lifting mechanism 2 correspond and set up in the both sides of ship shape body 3, and the first lifting mechanism 1 and second lifting mechanism 2 that set up at same water flat line make first clamping part 4 and second clamping part 5 respectively the optic fibre 6 of centre gripping be in same water flat line, realization butt fusion that can be better.

First clamping part 4 sets up in first lifting mechanism 1 top, first lifting mechanism 1 includes first base 11, first horizontal rail 12, first vertical rail 13, first horizontal drive subassembly 14 and first vertical drive subassembly 15, first clamping part 4 is connected with first base 11 top through first horizontal rail 12, first horizontal drive gets 14 and connects first base 11 and first clamping part 4 simultaneously, be used for driving first clamping part 4 and realize horizontal migration on first base 11 through first horizontal rail 12, make the optic fibre 6 of placing on first clamping part 4 be close to or keep away from the electrode needle on the ship shape body 3, first vertical rail 13 is used for connecting first base 11 and first vertical drive subassembly 15, be used for realizing reciprocating of first base 11 and first clamping part 4, thereby drive reciprocating of optic fibre 6.

Wherein the first horizontal rail 12 comprises a first slider 121 and a first slideway 122, and the first vertical rail 13 comprises a second slider 131 and a second slideway 132; the first horizontal driving assembly 14 comprises a first horizontal motor 141, a first horizontal fixing member 142, a first horizontal pushing member 143, a first threaded sleeve 144 and a first screw 145, the first horizontal fixing member 142 is fixedly arranged on the first base 11 through bolts and used for fixing the position of the first horizontal motor 141, the first screw 145 is fixedly arranged on an output shaft of the first horizontal motor 141, the first screw 145 is movably connected with the first threaded sleeve 144 through threads, the first threaded sleeve 144 is attached to the first horizontal pushing member 143, one end of the first threaded sleeve 144, which is far away from the first horizontal pushing member 143, is connected with a threaded sleeve pushing plate sleeved on a rod member extending out of the first horizontal fixing member 142, and the threaded sleeve pushing plate and the first threaded sleeve 144 synchronously move; the first horizontal pushing member 143 is fixedly connected to one end of the first clamping member 4 close to the boat 3, and when the first horizontal motor 141 is turned on, the first screw 145 is driven to rotate, so as to horizontally move the first thread bush 144, and thus the first clamping member 4 is driven to horizontally move by the first horizontal pushing member 143, the first horizontal pushing member 143 is fixed to a connecting seat connecting between the fiber clamping base 41 and the first horizontal rail 12, so that the fiber clamping base 41 moves along the direction of the first horizontal rail 12 in the horizontal direction relative to the first base 11 (wherein, it should be noted that the moving distance of the first thread bush 144 is set by a program of a control end, and does not disengage from the first screw 145 in the moving process, and the setting technology of the program is well known by those skilled in the art, and will not be described herein again.

The first vertical driving assembly 15 comprises a first vertical motor 151, a first vertical fixing member 152, a first vertical pushing member 153, a first rotating disc 154 and a first bearing 155, the first vertical motor 151 is fixedly arranged on the first vertical fixing member 152 through bolts, the first vertical fixing member 152 is fixedly connected with the first vertical rail 13, the first rotating disc 154 is fixedly connected to an output shaft of the first vertical motor 151, a first bearing 155 is arranged on an eccentric shaft of the first rotating disc 154 and is laterally connected with the first vertical pushing member 153, the first vertical pushing member 153 is fixedly arranged on the first base, when the first vertical motor 151 starts to rotate, the first rotating disc 154 is driven to rotate, so that the first bearing 155 rotates around the eccentric shaft of the first rotating disc 154, and the first vertical pushing member 153 laterally connected with the first bearing 155 drives the first base 11, the first clamping part 4 and the first vertical driving assembly 15 to move relatively along the direction of the first vertical rail 13 in the vertical direction. A first spring 71 is disposed between the first base 11 and the first vertical fixing member 152, when the first lifting mechanism 1 is in the descending position, the first spring 71 is in an initial state (the first spring 71 is not shown in the drawing), and when the first lifting mechanism 1 is in the ascending state, the first spring 71 is stretched to generate an elastic force, which can help the first lifting mechanism 1 to return to the descending position. In other embodiments, the first horizontal driving assembly 14 and the first vertical driving assembly 15 can be used as standard components, and the positions of the components can be replaced with each other, and the orientation of the first horizontal driving assembly 14 and the first vertical driving assembly 15 and the positions of the components connected with other structures can be adjusted adaptively during replacement.

The second lifting mechanism 2 comprises a second base 21, a second horizontal rail 22, a second vertical rail 23, a second horizontal driving assembly 24 and a second vertical driving assembly 25, and the second clamping component 5 is connected with the top of the second base 22 through the second horizontal rail 22. In the present application, the second lifting mechanism 2 is obtained by rotating the first lifting mechanism 1 by 180 ° along the central axis of the boat 3, and the structure thereof is the same as that of the first lifting mechanism 1, and therefore, the description thereof is omitted. In other embodiments, the second lifting mechanism 2 may be arranged symmetrically to the first lifting mechanism 1 along the central axis of the boat 3.

An optical fiber clamp base 41 matched with the optical fiber 6 is arranged on the first clamping part 4, the optical fiber clamp base 41 is matched with the optical fibers 6 of different types through a spring, a spongy cushion and the like (the clamping parts in the group are the existing universal clamping parts, so that description is not provided in the scheme), the position of the optical fiber 6 in the fusion process is kept relatively fixed with the first clamping part 4, and a first clamping part cover plate 42 is hinged to the first clamping part 4; offer the second centre gripping anchor clamps base 51 who agrees with optic fibre protection piece 61 on the second clamping part 5, optic fibre protection piece 61 suit is on optic fibre 6 is outside, be provided with two protection cover 62 that can open and shut on the optic fibre protection piece 61, protection cover 62 can be as an organic whole through the film bonding after the closure, protect the butt fusion part after two optic fibre 6 butt fusion, the optic fibre protection piece 61 that adopts in this application exempts from pyrocondensation fusible type connector for the SC, it has second clamping part apron 52 to articulate on the second clamping part 5.

The working principle is as follows: during the fusion splicing operation, the lifting mechanism is in a descending state, one optical fiber 6 and the other optical fiber 6 sleeved with the optical fiber protection member 61 are respectively placed in the two groups of clamping components, the fusion spliced part of the optical fiber 6 is a bare fiber, the optical fiber 6 provided with the optical fiber protection member 61 is a processed bare fiber, the other optical fiber 6 needs to be processed during the fusion splicing, and the protection sleeve member 62 is in a separated state; after placing optic fibre 6, open the optical fiber splicer, first horizontal drive subassembly 14 and second horizontal drive subassembly 24 drive first clamping part 4 and second clamping part 5 respectively and are close to the removal of bodoidal body 3, after the terminal surface contact of two optic fibre 6, the electrode needle on the bodoidal body 3 discharges and makes optic fibre 6 butt fusion be an optic fibre 6, then first vertical drive subassembly 15 and the vertical drive subassembly 25 of second drive two sets of lifting mechanisms and two sets of clamping part synchronous rises simultaneously, will part two protective sheath spare 62 closures after the rise, make protective sheath spare 62 pass through the film bonding as an organic whole, the butt fusion part of optic fibre 6 is closely wrapped up by protective sheath spare 62, open the clamping part apron at this moment and take off the optic fibre 6 that the butt fusion is good, and will lift mechanism and clamping part and resume to the initial position, be convenient for the butt fusion of next optic fibre 6.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments or portions thereof without departing from the spirit and scope of the invention.

Claims (10)

1. The utility model provides an optical fiber splicer's operating system, includes two sets of lifting mechanism, the ship physique, two sets of hold-in components, lifting mechanism set up relatively in the both sides of ship physique, its characterized in that: each group of the lifting mechanisms is provided with a group of the clamping components;

the two groups of clamping components respectively clamp one optical fiber;

every group the lifting mechanism contains two sets of drive assembly, every group drive assembly is used for driving respectively the removal of vertical direction or horizontal direction is realized to the hold assembly to realize the butt fusion of optic fibre.

2. An elevating system of an optical fiber fusion splicer according to claim 1, wherein: the clamping component is provided with a clamping component cover plate, the clamping component cover plate is movably connected with the clamping component, the two groups of clamping components are respectively a first clamping component and a second clamping component, the first clamping component comprises an optical fiber clamp base for placing optical fibers, and the second clamping component comprises a second clamping clamp base matched with the shape of an optical fiber protection piece.

3. An elevating system of an optical fiber fusion splicer according to claim 1, wherein: every group the lifting mechanism still contains base and two sets of tracks, and is two sets of the track all set up in on the base.

4. An elevating system of an optical fiber fusion splicer according to claim 3, wherein: the two groups of driving assemblies are respectively a horizontal driving assembly and a vertical driving assembly.

5. An elevating system of an optical fiber fusion splicer according to claim 4, wherein: the horizontal driving assembly is connected with the horizontal rail and used for driving the horizontal movement of the clamping component.

6. An elevating system of an optical fiber fusion splicer according to claim 4, wherein: the vertical driving assembly is connected with the vertical rail and used for driving the base to move up and down.

7. An elevating system of an optical fiber fusion splicer according to claim 2, wherein: the lifting mechanism comprises a first lifting mechanism and a second lifting mechanism.

8. An elevating system of an optical fiber fusion splicer according to claim 7, wherein: the first clamping part corresponds to the first lifting mechanism, and the second clamping part corresponds to the second lifting mechanism.

9. An elevating system of an optical fiber fusion splicer according to claim 4, wherein: a spring is arranged between the base and the vertical driving component.

10. An elevating system of an optical fiber fusion splicer according to claim 9, wherein: when the lifting mechanism is in a descending position, the spring is in an initial state.

Images