KR102086429B1 - Optical fiber interface adapter being capable of horizontalizing optical fiber - Google Patents

Abstract

The present invention relates to an optical fiber fusing technology, and more particularly, to an optical fiber fusing apparatus capable of horizontalizing an optical fiber, which realizes reliable and stable optical fiber fusion by maintaining horizontality of an optical fiber in an optical fiber alignment process for fusion. The optical fiber fusing apparatus of the present invention comprises: a main body having an alignment module for fixing and aligning first and second optical fibers to be fused and bonded, and a fusion module for fusing and bonding the first and second optical fibers fixed and aligned to the alignment module; and a cover hinged to one side of the main body to open and close an upper surface of the main body. The alignment module includes: first and second holder bases provided to be symmetrical to the main body, and inclined at a predetermined angle by elastic force in a horizontal state; a first holder for receiving the first optical fiber, and having horizontality in a state that the first holder base is inclined by being coupled to one side of an upper surface of the first holder base using a magnet; and a second holder for receiving the second optical fiber, and having horizontality in a state that the second holder base is inclined by being coupled to one side of an upper surface of the second holder base using a magnet.

Description

Optical fiber interface adapter being capable of horizontalizing optical fiber

The present invention relates to an optical fiber fusion technology, and more particularly, to an optical fiber fusion device capable of horizontally aligning an optical fiber to realize a reliable and stable optical fiber fusion by maintaining the optical fiber level in the optical fiber alignment process for fusion.

In general, an optical fiber (or an optical cable) is an optical signal, and unlike a wire for transmitting an electrical signal, a large amount of information can be transmitted without loss at a very high speed.

Since the optical cable cannot be manufactured by the manufacturer for an indefinite long length, it is usually manufactured to a length of about 2 km and wound on the drum. Therefore, in order to install the optical cable to a long distance, it is necessary to connect or branch it in the middle.

However, since the inner core of the optical cable consists of a very small diameter optical fiber, it is very difficult to connect the optical fibers with each other.

As the splicing method of the optical fiber, a fusion splicing method using an optical fiber splicer and a mechanical splicing method using an optical adapter or an optical connector are mainly used.

Important elements of the fiber splicer used in the fusion splicing method are to align the optical fiber accurately and stably, to stably separate the splicer from the splicer without breakage of the splice after the spliced splicing of the optical fiber, and the mechanical operation or components of the fiber splicer. To eliminate alignment errors that occur during mechanical coupling.

Therefore, in the conventional fusion splicing technology, there is a demand for a solution for solving the problems of the alignment, stable separation, and elimination of alignment error.

On the other hand, Korean Patent Laid-Open Publication No. 10-2014-0004719 discloses a method for fusion splicing of optical fibers and a fusion splicer. The electrode rods are arranged after aligning the optical fibers in the v-groove by coupling the holder containing the optical fibers to the fusion splicer. The fusion splicing is made by discharging. After the fusion splicing is completed, the fusion splicing operation is completed while separating the holder from the splicer. The present publication discloses a technique of providing a reinforcing member at a rear end of a ferrule, and then reinforcing the fusion site by overlapping the optical fiber with the reinforcing member overlapping the fusion splicing.

In this prior art, the holder is tilted 2.3 degrees inward (down from the fusion machine reference) to fix the optical fiber and the optical fiber in the v-groove. That is, the holder receiving the optical fiber is inclined 2.3 degrees, as the fusion module with the electrode is raised, the optical fiber is in contact with the surface of one side of the v-groove, and thus the optical fiber is bent by elasticity to terminate the end of the optical fiber aligned horizontally in the v-groove.

Meanwhile, after the fusion connection is completed, the fusion module is lowered and then the reinforcing member is overlapped to cover the fusion site. However, since the holders on both sides are inclined toward the center, the fusion portion of the optical fiber is in a bent shape, and as the reinforcing member is superimposed on the fusion region of the bent state, the fusion point is completed by the restoring force of the optical fiber when the fusion is completed. Site) cracked or cracked.

An object of the present invention has been made in view of the above points, in particular when the fusion splicing process proceeds to overlap the reinforcing member for reinforcing the fusion site after the fusion is completed while being aligned to the v-groove in an inclined state The present invention relates to an optical fiber fusion splicer capable of leveling an optical fiber that maintains the optical fiber level to realize a reliable and stable optical fiber fusion.

In order to achieve the above object, the optical fiber fusion splicer according to the present invention is characterized in that the alignment module for fixing and aligning the first and second optical fibers to be fused and the first fixed and aligned to the alignment module A main body having a fusion module for fusion-combining 1 and 2 optical fibers; And a cover coupled to one side of the main body to open and close the upper surface of the main body, wherein the alignment module is symmetrically provided on the main body and is inclined by a predetermined angle by an elastic force in a horizontal state. Accommodate a holder base, a second holder base, and the first optical fiber and a magnet coupled to one side of an upper surface of the first holder base to accommodate the first holder and the second optical fiber that are horizontal in the inclined state of the first holder base. And a second holder that is magnetically coupled to one side of an upper surface of the second holder base and is horizontal in the inclined state of the second holder base.

Preferably, the welding module is disposed between the first holder base and the second holder base and includes a first groove supporting the first optical fiber extending from the first holder and the second holder extending from the second holder. And a groove having a second groove for supporting the optical fiber, and an electrode rod for fusion-bonding the first and second optical fibers aligned to face the groove.

More preferably, the fusion module may be provided to move up and down.

Preferably, when the cover closes the upper surface of the main body, the first plate spring and the second holder for pressing the front side of the first holder so that the first holder is parallel to the first holder base. It may be configured to include a second plate spring for pressing the front side portion of the first holder to face in parallel to the second holder base.

More preferably, as the first holder is magnetically coupled to one side of the upper surface of the first holder base, a part of the first holder is horizontally disposed to be spaced apart from the upper surface of the first holder base, and the second holder is disposed in the horizontal direction of the second holder base. As the magnet is coupled to one side of the upper surface, a part of the second holder base may be horizontally spaced apart from the upper surface of the second holder base.

More preferably, as the cover closes the upper surface of the main body, the front side portion is pressed by the first leaf spring, so that the magnetic coupling with one side of the upper surface of the first holder base is separated. A surface spaced apart from an upper surface of the first holder base is disposed in parallel with the first holder base inclined to face the upper surface of the first holder base, and the second holder has the cover closing the upper surface of the main body. As the front plate is pressed by the second leaf spring, the magnetic coupling with one side of the upper surface of the second holder base is separated, and the surface spaced apart from the upper surface of the second holder base faces the upper surface of the second holder base. While being inclined may be disposed in parallel with the second holder base.

Preferably, the first holder detachably accommodates an optical connector including a ferrule in which the first optical fiber is embedded, and adheres the fusion site of the first optical fiber and the second optical fiber to face each other so that the fusion site is attached to the first holder. A protective cover to cover may be further provided at the rear end of the optical connector.

More preferably, the protective cover is coupled to the rear end of the optical connector is a pair of wings unfolded from the first optical fiber, provided with an elastic sheet coated with an adhesive on the inner surface of the wing portion to be bonded to each other or the mutual adhesion Silicon coated on the inner surface of the wing may be provided.

According to the present invention, when the fusion splicing proceeds, it is possible to ensure stable fusion because it is aligned with the v-groove in an inclined state, and in the process of reinforcing the fusion site after the fusion is completed, the protective cover (reinforcement) is maintained in a horizontal state. Member), the connection point (fusion site) is broken or cracks can be solved by the restoring force of the optical fiber.

1 is a perspective view showing the overall configuration of a fiber fusion splicer capable of leveling the optical fiber according to the present invention,
2 is a plan view showing the overall configuration of the optical fiber fusion splicer capable of leveling the optical fiber according to the present invention,
3 to 5 are diagrams for explaining the alignment and fusion of the optical fiber in the optical fiber fusion splicer capable of leveling according to the present invention,
6 to 8 are diagrams for explaining the post-fusion reinforcement of the optical fiber in the optical fiber splicer capable of leveling the optical fiber according to the present invention.

Other objects, features and advantages of the present invention will become apparent from the detailed description of the embodiments with reference to the accompanying drawings.

Hereinafter, with reference to the accompanying drawings illustrating the configuration and operation of the embodiment of the present invention, the configuration and operation of the present invention shown in the drawings and described by it will be described by at least one embodiment, By the technical spirit of the present invention described above and its core configuration and operation is not limited.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the optical fiber fusion splicer capable of leveling the optical fiber according to the present invention.

1 is a perspective view showing the overall configuration of the optical fiber fusion splicer capable of leveling the optical fiber according to the present invention, Figure 2 is a plan view showing the overall configuration of the optical fiber fusion splicer capable of leveling the optical fiber according to the invention, Figures 3 to 5 Are diagrams for explaining the alignment and fusion of the optical fiber in the optical fiber fusion splicer according to the present invention, Figure 6 to 8 for the post-fusion reinforcement of the optical fiber in the optical fiber fusion splicer according to the present invention Diagrams for explanation.

1 to 8, the optical fiber fusion machine according to the present invention is largely composed of the main body (1) and the cover (2).

The main body 1 includes alignment modules 10 and 11 and a fusion module 20.

Alignment module (10,11) is a configuration for fixing and aligning the first and second optical fibers to be fusion-bonded, fusion module 20 is a first and second optical fiber fixed and aligned to the alignment module (10,11) It is a structure for fusion bonding.

In addition to the alignment modules 10 and 11 and the fusion module 20, the main body 1 includes a lens and a camera to align the first and second optical fibers by the alignment modules 10 and 11 and the fusion module 20. Optical module (not shown) for photographing the fusion bonding state of the first and second optical fibers by the elevating module (not shown), the elevating module (not shown) for raising and lowering the support fixed to the fusion module 20, the alignment module (10, 11) And a control button (not shown) for manipulating operations of the fusion module 20 and the optical module 30, a display unit (not shown) for displaying an image photographed by the optical module (not shown), and power supply. It may further include a battery (not shown) and a power supply port (not shown), and a data communication port (not shown) for data transmission and reception.

The alignment modules 10 and 20 are composed of a first alignment module 10 and a second alignment module 20 which are provided symmetrically on the main body 1.

The first alignment module 10 includes the first holder base 11 and the first holder 12, and the second alignment module 20 includes the second holder base 21 and the second holder 22. do.

The first holder base 11 and the second holder base 21 may be provided to be inclined by a predetermined angle by an elastic force in a horizontal state. It can be tilted down in the horizontal state or it can be leveled back up in the tilted state. For example, the first holder base 11 and the second holder base 21 may be tilted 2.3 degrees downward from the splicer reference to align the optical fiber with the v-groove provided in the groove 31 in a horizontal state.

The first holder 12 receives the first optical fiber, and the second holder 22 receives the second optical fiber. Here, the first optical fiber and the second optical fiber is the object to be fusion-bonded.

In particular, the first holder 12 is detachably accommodating an optical connector including a ferrule in which the first optical fiber is embedded, and the second holder 22 is detachable in the optical connector including a ferrule in which the second optical fiber is embedded. Accept it.

The first holder base 11 and the second holder base 21 detachably fix the first holder 12 and the second holder 22. To this end, the first holder base 11 and the second holder base 21 have protruding bars, and the first holder 12 and the second holder 22 have a plurality of through holes fitted to the protruding bars. Accordingly, the plurality of through holes respectively provided in the first holder 12 and the second holder 22 are fitted into the first holder base 11 and the second holder base 21 of the protruding rod structure, respectively. do. Here, it is preferable that one side of the holder 12, 22 has a certain degree of freedom in the vertical direction between the holder 12, 22 and the holder base 11, 21.

The degree of freedom between the holders 12 and 22 and the holder bases 11 and 21 is further controlled by a magnet (not shown) provided in at least one of the holders 12 and 22 and the holder bases 11 and 21. .

In more detail, the first holder 12 is magnetically coupled to one side of the upper surface of the first holder base 11 in a state where the first holder 12 is fitted to the protruding rod, and the second holder 22 has the second holder base 21 in the state where the second holder 22 is fitted to the protruding rod. Magnetically coupled to one side of the top surface. Accordingly, as shown in FIG. 7, the first holder 12 is horizontal even when the first holder base 11 is inclined, and the second holder 22 is inclined when the second holder base 21 is inclined. Even though the state is level.

In addition, the first holder 12 which is horizontal with respect to the first holder base 11 in an inclined state is parallel to the first holder base 11 as shown in FIG. 4 as pressure is applied from the upper side. Can be confronted. The second holder 22 which is horizontal with respect to the second holder base 21 in an inclined state may also face parallel to the second holder base 21 as shown in FIG. 4 as pressure is applied from the upper side. Can be. Here, the means for pressing the first holder 12 and the second holder 22 is a leaf spring 50 provided in the cover 2, which will be described later.

When the holders 12 and 22 face in parallel to the holder bases 11 and 21 as shown in FIG. 4, the optical fibers come into contact with the v-grooves of the grooves 31 such that the optical fibers are bent by elasticity and thus the optical fibers The ends of are aligned horizontally in the v-groove.

The fusion module 30 is disposed between the first holder base 11 and the second holder base 21 and is provided to be able to move up and down.

The fusion module 30 includes a groove portion 31 for supporting the first and second optical fibers and an electrode rod 32 for fusion-bonding the first and second optical fibers when the optical fibers are fusion-coupled.

The groove 31 has a first groove (v-groove) for supporting the first optical fiber extending from the first holder 12 and a second groove (v-) for supporting the second optical fiber extending from the second holder 22. Home). In addition, the groove 31 may have at least two v-grooves.

The electrode 32 discharges by the applied power and fusion bonds the first and second optical fibers aligned with the groove portion 31.

The optical fiber fusion machine of the present invention includes a cover 2 covering the fusion module 30 when fusion splicing is performed by the electrode rod 32 provided in the fusion module 30, and the cover 2 is covered. LED lighting illuminators (not shown) may be further provided therein to enable internal imaging by an optical module (not shown).

On the other hand, the first holder 12 fixed to the first holder base 11 is detachably accommodated in the optical connector including a ferrule in which the first optical fiber is embedded, the optical connector at the rear end of the first optical fiber and the second It is provided with a protective cover 40 for bonding the fusion portion of the optical fiber facing each other to cover the fusion portion.

The protective cover 40 is coupled to one end of the optical connector, in particular, the rear end of the pair of wings 41 extending from the first optical fiber. In particular, the inner surface of the wing portion 41 is provided with a member for bonding to each other.

For example, an elastic sheet coated with an adhesive may be provided on the inner surface of the wing part 41. The material of the elastic sheet may be any one of polyethylene, polyvinyl chloride, polyurethane, natural rubber, synthetic rubber, and a mixture of natural rubber and synthetic rubber. As another example, silicon may be applied to the inner surface of the wing 41. While being bonded to the inner surface of the pair of wings 41 constituting the protective cover 40 is covered to wrap the fusion by elasticity.

On the other hand, the outer side of the wing portion 41 is preferably made of a hard rigid material in order to prevent the fusion site bending.

The cover 2 is hinged to one side of the main body 1 is configured to open and close the upper surface of the main body (1).

The cover 2 has first and second leaf springs 50.

When the first and second leaf springs 50 close the upper surface of the main body 1, the front side of the first holder 12 such that the first holder 12 faces in parallel to the first holder base 11. And press the front side of the first holder 22 so that the second holder 22 faces in parallel to the second holder base 21. Preferably, the first and second leaf springs 50 are configured to be separated such that the first leaf spring presses the first holder 12 and the second leaf spring presses the second holder 22.

3 to 5 show that the first and second leaf springs 50 cover the first holder 12 in a state in which the cover 2 closes the upper surface of the main bike 1 so that the cover 2 is covered with the main body 1. And pressing the front side portions of the second holder 22 to form a shape in which the first holder 12 and the second holder 22 face the first holder base 11 and the second holder base 21 in parallel. As shown, it is an arrangement structure at the time of fusion bonding the 1st and 2nd optical fiber.

The first holder 12 is pressurized by the first leaf spring, so that the magnetic coupling with one side of the upper surface of the first holder base 11 is separated, and the surface spaced apart from the upper surface of the first holder base 11 is formed. The first holder base 11 is disposed in parallel with the upper surface of the first holder base 11 while being inclined.

The second holder 22 is pressurized by the second plate spring, so that the magnetic coupling with one side of the upper surface of the second holder base 21 is separated, and the surface spaced apart from the upper surface of the second holder base 21 is first. The second holder base 21 is disposed in parallel with the second holder base 21 inclined while facing the upper surface of the holder base 21.

6 to 8 illustrate that the holders 12 and 22 are magnetically coupled to the holder base 11 by the cover 2 being opened from the upper surface of the main body 1 so that the cover 2 is opened in the main body 1. 21 shows a horizontal shape spaced apart from the cover, and the fusion portion is covered with the protective cover 40 after the fusion bonding is performed in a state in which the holders 12 and 22 are disposed parallel to the holder bases 11 and 21. In the batch structure.

As the first holder 12 is magnetically coupled to one side of the upper surface of the first holder base 11, a part of the first holder 12 is horizontally disposed to be spaced apart from the upper surface of the first holder base 11, and the second holder 22 is disposed in the second holder 22. As the magnet is coupled to one side of the upper surface of the holder base 21, a portion thereof is horizontally spaced apart from the upper surface of the second holder base 21.

As described above, in the present invention, when the cover 12 is fused with the protective cover 40, the holders 12 and 22 are horizontally aligned by magnetic coupling, thereby causing peripheral interference generated when the protective cover 40 is folded. Can be minimized.

Although the preferred embodiments of the present invention have been described so far, those skilled in the art may implement the present invention in a modified form without departing from the essential characteristics of the present invention.

Therefore, the embodiments of the present invention described herein are to be considered in descriptive sense only and not for purposes of limitation, and the scope of the present invention is shown in the appended claims rather than the foregoing description, and all differences within the scope are equivalent to the present invention. Should be interpreted as being included in

1: main body
2: cover
10,20: alignment module
11,21: holder base
12,22: holder
30: fusion module
40: protective cover
41: wing
50: leaf spring

Claims (8)

A main body having an alignment module for fixing and aligning the first and second optical fibers to be fused and a fusion module for fusion coupling the first and second optical fibers fixed and aligned to the alignment module; And
Is hinged to one side of the main body consists of a cover for opening and closing the upper surface of the main body,
The alignment module,
It is provided symmetrically on the main body and accommodates the first holder base and the second holder base, the first optical fiber is provided to be inclined by a predetermined angle by the elastic force in a horizontal state and is magnetically coupled to one side of the upper surface of the first holder base A first holder accommodating the first holder and the second optical fiber that are horizontal in an inclined state of the first holder base and being magnetically coupled to one side of an upper surface of the second holder base to be horizontal in the inclined state of the second holder base; It consists of two holders,
The cover,
When closing the upper surface of the main body, the first plate spring and the second holder to press the front side portion of the first holder so that the first holder faces in parallel to the first holder base, the second holder base A second leaf spring for urging the front side of the first holder to face in parallel with
The first holder is arranged to be horizontally spaced apart from the upper surface of the first holder base as the magnet is coupled to one side of the upper surface of the first holder base, the second holder is a magnet on one side of the upper surface of the second holder base As the portion is spaced apart from the upper surface of the second holder base horizontally arranged,
As the cover closes the upper surface of the main body, the first holder is pressurized by the first leaf spring so that the magnetic coupling with one side of the upper surface of the first holder base is separated. A surface spaced apart from an upper surface is disposed in parallel with the first holder base which is inclined while facing the upper surface of the first holder base, and the second holder is formed in such a manner that the cover closes the upper surface of the main body. The front side portion is pressed by the two leaf springs so that the magnetic coupling with one side of the upper surface of the second holder base is separated, and the surface spaced apart from the upper surface of the second holder base is inclined while facing the upper surface of the second holder base. The optical fiber fusion splicer capable of leveling the optical fiber, characterized in that arranged in parallel with the second holder base. The method of claim 1,
The fusion module,
A first groove disposed between the first holder base and the second holder base and supporting the first optical fiber extending from the first holder and a second groove supporting the second optical fiber extending from the second holder; Grooves provided with,
And an electrode rod for fusion-bonding the first and second optical fibers arranged to face the groove portion. The method of claim 2,
The fusion module is optical fiber fusion fusion possible, characterized in that provided with a lifting module. delete delete delete The method of claim 1,
The first holder detachably accommodates an optical connector including a ferrule in which the first optical fiber is embedded,
The optical fiber fusion splicer of claim 1, further comprising a protective cover at the rear end of the optical connector by adhering the fusion portion of the first optical fiber and the second optical fiber to face each other. The method of claim 7, wherein
The protective cover,
A pair of wing portions extending from the first optical fiber is coupled to a rear end of the optical connector, and an elastic sheet coated with an adhesive is provided on the inner side of the wing portions to be bonded to each other, or applied to the inner side of the wing portions to be bonded to each other. Optical fiber fusion splicer, characterized in that the silicon is provided.

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