CN220121025U - Optical fiber fusion splicer - Google Patents

Abstract

The utility model discloses an optical fiber fusion splicer, which comprises a fusion splicer shell, a ship-shaped body and an optical fiber clamping system, wherein the ship-shaped body and the optical fiber clamping system are arranged in an inner cavity of the fusion splicer shell, the ship-shaped body moves up and down through a central sliding component, the optical fiber clamping system moves up and down through a vertical sliding component, and when the ship-shaped body moves to the lowest position or when the optical fiber clamping system moves to the highest position, a thermal shrinkage-free optical fiber connector can have enough space to protect a fusion splicing part; after the optical fibers are welded, the boat-shaped body can be moved downwards or the optical fiber clamping system can be moved upwards, so that enough space is reserved on the welded part, the adhesion of the protection element is not affected, the protection of the welded part can be finished, and the possibility of breakage of bare fibers in the process of protecting the welded part is effectively reduced.

Description

Optical fiber fusion splicer

Technical Field

The utility model relates to the field of optical fiber fusion welding equipment, in particular to an optical fiber fusion welding machine.

Background

The optical fiber fusion splicer is equipment for fusing two sections of optical fibers into one optical fiber by discharging through an electrode needle, and can improve the fusion success rate of the optical fibers.

The existing optical fiber fusion splicer is matched with an optical fiber connector with a heat shrinkage pipe, after the optical fiber fusion splices successfully, the heat shrinkage pipe is further subjected to heat shrinkage to better protect a fusion splice part, but when the fused optical fiber is transferred, the optical fiber is very thin and is easy to break, the heat shrinkage pipe is easy to break, and the heat shrinkage pipe and the heat fusion splice part of the existing optical fiber fusion splicer cannot be in a closed state when the heat shrinkage pipe is subjected to heat shrinkage, so that the heat shrinkage pipe cannot be in a corresponding state, the heat shrinkage effect cannot be ensured, the protection effect on the fusion splice part cannot be ensured, and the fusion splice part cannot be effectively protected or does not correspond to the fusion splice part when the heat shrinkage pipe is subjected to heat shrinkage, so that the heat fusion fails.

Disclosure of Invention

The utility model aims to solve the defects in the prior art and provides an optical fiber fusion splicer.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: including the welding machine casing, marine body and optic fibre clamping system, marine body with optic fibre clamping system sets up in the inner chamber of welding machine casing, its characterized in that: the ship-shaped body moves up and down through the central sliding component;

when the boat moves to the lowest position, the fiber optic connector that does not require heat shrinkage can have sufficient space to protect the fusion splice.

As a further description of the above technical solution: the center slide assembly includes a center slide and a center slide rail.

As a further description of the above technical solution: the central slide piece and the central slide rail are respectively fixed on the shell cover plate and the ship-shaped body.

As a further description of the above technical solution: the welder housing further comprises a heater, a battery assembly and a body cover.

As a further description of the above technical solution: the heater is arranged on the machine body cover plate, and at least two button cover plates are arranged on the machine body cover plate.

As a further description of the above technical solution: the machine body cover is hinged with the welding machine shell, a control screen is arranged outside the welding machine shell at the hinge joint, and the battery assembly is arranged at the bottom of the inner cavity of the welding machine shell.

As a further description of the above technical solution: the inner wall of the machine body cover is provided with an XY lamp panel, and pressure head assemblies are arranged on two sides of the XY lamp panel.

As a further description of the above technical solution: the structure is comprised of the above-mentioned structure,

the optical fiber clamping system moves up and down through the vertical sliding component;

the vertical sliding component comprises a vertical sliding piece and a vertical sliding rail;

the fiber optic connector, which does not require heat shrinkage, can have sufficient space to protect the fusion splice when the fiber clamping system is moved to the highest position.

As a further description of the above technical solution: the fiber clamping system includes a clamping base, a vertical drive assembly, and a horizontal drive assembly.

As a further description of the above technical solution: the vertical slider and the vertical slide rail are respectively fixed on the clamping base and the vertical driving assembly.

The utility model has the following beneficial effects:

according to the utility model, the ship-shaped body or the optical fiber clamping system can move up and down through the central sliding assembly or the vertical sliding assembly, and after the optical fiber welding is finished, through the welding machine capable of moving the ship-shaped body downwards or the optical fiber clamping system upwards, enough space can be reserved at the welding part under the condition that the optical fiber is not taken down, so that the protection element can be adhered to complete the protection of bare fibers at the welding part, the possibility of breakage of the welding part caused by the movement of the optical fiber in the process of protecting the welding part is effectively reduced, and the welding success rate of the optical fiber is improved.

Drawings

FIG. 1 is a front view of an optical fiber fusion splicer according to the present utility model;

FIG. 2 is a perspective view of the welder housing of FIG. 1;

FIG. 3 is a perspective view of the boat-shaped body and the raised fiber clamping system of FIG. 1;

fig. 4 is a perspective view of the cover plate of the case of fig. 1 and the ship body after being lowered.

Legend description:

1. a fusion splicer housing; 2. a boat-shaped body; 3. a fiber clamping system; 11. a housing cover plate; 12. a heater; 13. a battery assembly; 14. a housing cover; 15. a control screen; 21. a central sliding assembly; 22. an electrode needle; 31. a vertical sliding assembly; 32. clamping a base; 33. a vertical drive assembly; 34. a horizontal drive assembly; 111. a button cover plate; 141. an XY lamp panel; 142. a ram assembly; 211. a center slide; 212. a central slide rail; 311. a vertical slider; 312. and a vertical slide rail.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-3, one embodiment provided by the present utility model is: the optical fiber connector comprises a fusion splicer shell 1, a ship-shaped body 2 and an optical fiber clamping system 3, wherein the ship-shaped body 2 and the optical fiber clamping system 3 are arranged in the inner cavity of the fusion splicer shell 1, the ship-shaped body 2 moves up and down through a central sliding component 21, and when the ship-shaped body 2 moves to the lowest position, the optical fiber connector without thermal shrinkage can have enough space to protect a fusion splice part; after the two optical fibers are welded through the electrode needle 22, the boat-shaped body 2 can be moved downwards through the central sliding component 21, so that the welded part is kept with the largest space to finish protection, and the possibility of breaking the bare fibers in the process of protecting the welded part can be effectively reduced.

Opening a shell plate 14 to expose a ship-shaped body 2 and an optical fiber clamping system 3 in a shell 1 of a fusion splicer, respectively fixing two optical fibers on the optical fiber clamping systems 3 on two sides of the ship-shaped body 2 through a clamping base 31, wherein an optical fiber connector is arranged on one optical fiber, after clamping, a control screen 15 enables a horizontal moving component on the optical fiber clamping systems 3 on two sides to drive the optical fiber clamping systems 3 to automatically approach the ship-shaped body 2 and enable the end faces of the optical fibers to be aligned automatically, the aligned optical fibers are welded into one optical fiber through an electrode needle 22 in a discharging way, after the optical fibers are welded into one optical fiber, a central sliding component 21 can be enabled to drive the ship-shaped body 2 to move downwards through the control screen 15, the welding part is far away from the electrode needle 22 and the ship-shaped body 2, enough operation space can be realized for protecting the welding part, and a protection element is closed through a thermal shrinkage-free connector (the thermal shrinkage-free connector is different from the existing thermal shrinkage-free connector, a protection element is detachably connected with the connector, and the two protection elements are combined to occupy the upper part through a welding strip, and the situation of the utility model is not covered by other special protection structures, and the situation of the utility model is reduced, and the situation of the rupture is not mainly met; or the optical fiber is protected by a connector with a heat shrink tube, and after the welding part is far away from the electrode needle 22, more operation space is reserved for a worker to take down the optical fiber, so that the condition that the welding part is hung up by the electrode needle 22 or the boat-shaped body 2 in the process of taking out the optical fiber is reduced.

The center slide assembly 21 includes a center slide 211 and a center slide rail 212, which are respectively fixed to the case cover 11 and the boat 2, and up and down movement of the boat 2 is achieved by the up and down movement of the center slide 211 in the center slide rail 212; the welding machine shell 1 further comprises a heater 12, a battery assembly 13 and a machine body cover 14, the shell cover 14 is hinged with the welding machine shell 1, a control screen 15 is arranged outside the welding machine shell 1 at the hinged position, the battery assembly 13 is arranged at the bottom of an inner cavity of the welding machine shell 1, the battery assembly 13 provides power for all parts of the welding machine, the control screen 15 is used for controlling movement and operation of all the parts, the heater 12 is arranged on a shell cover plate 11, the heater 12 is closed through a glass window, and at least two button cover plates 111 are further arranged on the shell cover plate 11 and used for protecting buttons arranged on the shell cover plate 11; the XY lamp plate 141 and the ram assembly 142 provided on the inner wall of the case cover 14 protect the boat 2 and the electrode needle 22 when the case cover 14 and the hot-melt machine case 14 are closed.

Embodiment two: referring to fig. 1-2 and 4, including the above-described fusion splicer housing 1 and the structure thereon, and the boat-shaped body 2, the fiber clamping system 3 is moved up and down by the vertical sliding assembly 31; the vertical sliding assembly 31 includes a vertical slider 311 and a vertical slide rail 312, and when the optical fiber clamping system 3 is moved to the highest position, the optical fiber connector without heat shrinkage can have enough space to protect the fusion-spliced portion; when the optical fiber clamping system 3 is moved up by the vertical sliding component 31 and the optical fiber clamping system 3 is moved to the highest position, the protection of the fusion splice can be completed without moving the fusion splice.

The vertical sliding component 31 comprises a vertical sliding piece 311 and a vertical sliding rail 312, which are respectively fixed on the clamping base 32 and the vertical driving component 33, so that the clamping base 32 drives the optical fiber and the vertical driving component 33 to move up and down relatively, and thus, the optical fiber and the fusion splicer shell 1 move relatively, the horizontal driving component 34 drives the horizontal sliding component to drive the clamping base 32 to move left and right through the control screen 15, so that the approach of two optical fibers in the fusion splicing process is completed (the lifting of the ship-shaped body 2 and the optical fiber clamping system 3 are reset through springs, the springs on the ship-shaped body 2 are respectively connected with the ship-shaped body 2 and the shell cover plate 11, the springs on the optical fiber clamping system 3 are respectively connected with the clamping base 32 and the vertical driving component 33, and the reset of the ship-shaped body 2 or the optical fiber clamping system 3 after the up and down movement is realized through the springs, so that the fusion splicer is used next time, and the center sliding component 21, the vertical sliding component 31 and the vertical driving component 33 drive the sliding component drive the sliding components to move relatively through motors, so that the horizontal movement or the vertical movement of the components are realized, and the battery component 13 and the control screen 15 are electrically connected, and the driving of the components is the prior art.

Finally, it should be noted that: the foregoing description is only illustrative of the preferred embodiments of the present utility model, and although the present utility model 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 described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements or changes may be made without departing from the spirit and principles of the present utility model.

Claims (10)

1. The utility model provides an optical fiber fusion splicer, includes fusion splicer casing (1), boat shape body (2) and optic fibre clamping system (3), boat shape body (2) with optic fibre clamping system (3) set up in the inner chamber of fusion splicer casing (1), its characterized in that: the ship-shaped body (2) moves up and down through the central sliding component (21);

when the boat (2) is moved to the lowest position, the optical fiber connector without heat shrinkage can have enough space to protect the fusion-spliced portion.

2. An optical fiber fusion splicer according to claim 1, characterized in that: the center slide assembly (21) includes a center slide (211) and a center slide rail (212).

3. An optical fiber fusion splicer according to claim 2, characterized in that: the central slide (211) and the central slide rail (212) are respectively fixed on the machine body cover plate (11) and the ship-shaped body (2).

4. An optical fiber fusion splicer according to claim 3, characterized in that: the welding machine shell (1) further comprises a heater (12), a battery assembly (13) and a machine body cover (14).

5. The optical fiber fusion splicer according to claim 4, wherein: the heater (12) is arranged on the machine body cover plate (11), and at least two button cover plates (111) are arranged on the machine body cover plate (11).

6. The optical fiber fusion splicer according to claim 4, wherein: the machine body cover (14) is hinged with the welding machine shell (1), a control screen (15) is arranged outside the welding machine shell (1) at the hinged position, and the battery assembly (13) is arranged at the bottom of the inner cavity of the welding machine shell (1).

7. The optical fiber fusion splicer according to claim 4, wherein: the inner wall of the machine body cover (14) is provided with an XY lamp panel (141), and pressure head assemblies (142) are arranged on two sides of the XY lamp panel (141).

8. An optical fiber fusion splicer according to claim 1, characterized in that:

the optical fiber clamping system (3) moves up and down through a vertical sliding component (31);

the vertical sliding assembly (31) comprises a vertical slider (311) and a vertical sliding rail (312);

when the optical fiber clamping system (3) is moved to the highest position, the optical fiber connector without heat shrinkage can have enough space to protect the fusion splice.

9. The optical fiber fusion splicer of claim 8, wherein: the fiber clamping system (3) comprises a clamping base (32), a vertical driving assembly (33) and a horizontal driving assembly (34).

10. An optical fiber fusion splicer according to claim 9, wherein: the vertical slider (311) and the vertical slide rail (312) are fixed to the clamping base (32) and the vertical drive assembly (33), respectively.