KR102512811B1 - Field-assembled fiber optic connector - Google Patents

Abstract

The present invention relates to a field-assembled fusion-spliced optical fiber connector, and more particularly, when installing an optical cable in the field, by providing some of the parts of the optical fiber connector in a pre-assembled state, so that the number of parts is significantly higher than before. The present invention relates to a field assembly type fusion splicing optical fiber connector that reduces work time, simplifies work, and prevents incorrect assembly of parts due to a large number of parts.

Description

Field-assembled fiber optic connector {Field-assembled fiber optic connector}

The present invention relates to a field assembly-type fusion splicing optical fiber connector that reduces the number of parts used in an optical cable fusion process in the field, thereby simplifying the work.

Recently, an FTTH (Fiber To The Home) system has been proposed and installed in apartments and houses to provide various information including broadcasting and communication by connecting optical cables to ordinary homes. In the FTTH system, an optical cable is connected to, for example, a home, and its end is installed in a connector form. At this time, the FTTH worker sets the optical cable several meters longer than the actual length in consideration of the connection between the optical cables and introduces them into the home. In addition, the worker cuts the optical cable to a required length in the home, which is a construction site, assembles an optical connector at the end, connects it to an optical adapter, and installs the optical cable in the home.

On the other hand, a general optical fiber is composed of a core layer and a cladding layer, and the diameter of the cladding is formed to be approximately 125 μm, and a coating layer is coated on the outside of the optical fiber to a thickness of approximately 250 μm or 900 μm (hereinafter, this is referred to as a core wire. ) An outer skin is coated on the outside of the coating layer (hereinafter referred to as a code line)

A jacket made of, for example, PVC is coated on the outside of the core wire through a cushioning material such as Kevlar (aramid yarn) for reinforcing tensile strength.

The optical fiber is capable of transmitting and receiving desired signals through light transmitted through the core layer. Therefore, during the construction of optical cables, it is necessary to accurately align and connect optical fibers in order to minimize transmission loss of light.

As described above, various technologies such as field assembly type optical connectors are being developed to accurately align and connect optical fibers in the field.

However, in the case of these various existing field assembly type optical connectors, the number of parts is large, so there is a problem that a lot of work time is required, and also problems such as incorrect assembling by a worker due to the large number of parts occur.

Republic of Korea Domestic Patent Registration No. 10-610148 (registered on 2006.08.01.) Republic of Korea Patent Publication No. 10-2009-78317 (published on July 17, 2009)

The present invention has been made to solve the above problems, and an object of the present invention is to provide an integrated structure in which some of the components of an optical fiber connector for this are pre-assembled when an optical cable is fused in the field, so that parts to be assembled As the number is significantly reduced compared to the conventional one, it is to provide a field assembly type fusion spliced optical fiber connector that can simplify work and prevent problems such as incorrect assembly between parts.

Other objects and advantages of the present invention will be described below, and will be learned by way of examples of the present invention. Furthermore, the objects and advantages of the present invention may be realized by means of the instrumentalities and combinations indicated in the claims.

The present invention is a means for solving the above problems,

In the field assembly type fusion spliced optical fiber connector,

A ferrule flange 11 through which the center is penetrated in the longitudinal direction, a locking protrusion 13 protruding the locking protrusion 12 is formed on the outer periphery at one end, and a screw thread is formed at the other end;

an optical fiber for a ferrule (A) disposed inside the ferrule flange 11 in a longitudinal direction and having both ends exposed to the outside from which the coating is peeled;

A ferrule 15 in which one end of the optical fiber A for the ferrule is inserted and fastened to one side of the ferrule flange 11;

A C ring 17 fastened to the outer periphery of the other end of the ferrule flange 11;

a washer installed on the outer periphery of the ferrule flange 11 and whose position is interrupted by the C-ring 17;

an elastic member 19 installed on the outer periphery between the locking shoulder 13 of the ferrule flange 11 and the washer, and tensioned/compressed according to the position of the washer;

The ferrule portion 10 made of is assembled integrally in advance and provided to the site,

When assembling the optical fiber connector in the field, by screwing the ferrule flange 11 and the coupling nut 30, the assembly process is easy with simplified parts, and there is no problem in the assembly sequence.

As described above, the present invention is to provide some of the parts of the optical connector for this in a pre-assembled state during the optical cable fusion process in the field, so as to work using significantly reduced parts compared to the conventional ones , the working time is reduced, the work is simplified, and there is an effect that the problem of incorrect assembly between parts does not occur.

1 and 2 are diagrams of one embodiment showing the structure of a field-assembled fusion-spliced optical fiber connector for Tight Buffer Fiber according to the present invention.
3 and 4 are diagrams of one embodiment showing the structure of a field assembly-type fusion-spliced optical fiber connector for Fiber Cord according to the present invention.

Before describing various embodiments of the present invention in detail, it will be appreciated that the application is not limited to the details of the configuration and arrangement of components described in the following detailed description or shown in the drawings. The invention is capable of being implemented and practiced in other embodiments and of being carried out in various ways. Also, device or element orientation (e.g., "front", "back", "up", "down", "top", "bottom") The expressions and predicates used herein with respect to terms such as ", "left", "right", "lateral", etc. are only used to simplify the description of the present invention and related devices. Or it will be appreciated that it does not indicate or imply that an element simply must have a particular orientation. Also, terms such as “first” and “second” are used herein and in the appended claims for descriptive purposes and are not intended to indicate or imply relative importance or significance.

The present invention has the following features to achieve the above object.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, the terms or words used in this specification and claims should not be construed as being limited to the usual or dictionary meaning, and the inventor appropriately uses the concept of the term in order to explain his/her invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, since the embodiments described in this specification and the configurations shown in the drawings are only one of the most preferred embodiments of the present invention and do not represent all of the technical ideas of the present invention, various alternatives may be used at the time of this application. It should be understood that there may be equivalents and variations.

Hereinafter, a field assembly type fusion-spliced optical fiber connector according to a preferred embodiment of the present invention will be described in detail with reference to FIGS. 1 to 4.

The field assembly type fusion spliced optical fiber connector according to the present invention includes a ferrule part 10 (ferrule flange 11), a bare fiber for ferrule (A), a ferrule 15, a C ring (C -Ring (17), Washer (18), Spring (19)), Heat Shrink Sleeve (20), Coupling Nut (30), Screw Cap ( Screw Cap) (40), Boot (50), Protection Tube (60), Bayonet Coupling (70), Dust Cap (80), Assembly Tool ( Ass'y Tool) (90).

In the present invention, among the above-described components (parts), the ferrule flange 11, the ferrule optical fiber A, the ferrule 15, the C ring 17, the washer 18, and the elastic member 19 are single As a part called the ferrule part 10, it is pre-assembled and provided to the site as an integral body, so that when assembling the optical fiber connector at the site, the assembly process is easy with simplified parts, and there is no problem in the assembly sequence. .

The ferrule part 10 is a part where the optical fiber A for ferrule is installed, and a plug connected to an optical adapter is installed at one end, and one end of the optical fiber A for ferrule is stripped of the coating, so that it is suitable for field conditions in the field. It is made to be fused with the main optical fiber (B) whose length is adjusted accordingly.

The ferrule part 10 for this includes a ferrule flange 11, an optical fiber for ferrule A, a ferrule 15, a C ring 17, a washer 18, and an elastic member 19.

The ferrule flange 11 has a circular cross section and has a shape through which a center is penetrated in the longitudinal direction. Once the locking jaw 13 is formed on the outer periphery, the locking protrusion 12 protrudes from the outer periphery of the locking jaw 13. In addition, a screw thread 14 is formed on the outer periphery of the other end, and a ring-shaped groove 16 is cut at the front end of the screw thread 14 so that a C-ring 17 to be described later can be mounted.

The optical fiber A for the ferrule has a shape in which both ends are accommodated in the center of the ferrule flange 11 in a state where the coating is peeled off, and both ends are exposed to the outside of the ferrule flange 11.

The ferrule 15 is used for aligning the optical fiber A for ferrule, and one side is fitted to one side of the ferrule flange 11 for a predetermined length, and one side of the optical fiber A for ferrule from which the coating is peeled is inside. to be inserted.

The C ring 17 is mounted in correspondence with the outer circumferential groove 16 of the ferrule flange 11 described above, so that a portion protrudes toward the outer circumference of the ferrule flange 11.

The washer 18 is installed on the outer periphery of the above-described ferrule flange 11, and is fitted to the front end of the C-ring 17, so that the washer 18 is connected to the locking jaw 13 of the ferrule flange 11 and It is made to be able to move in the longitudinal direction only between the C-rings 17, and is a part whose position is interrupted by the C-rings 17.

The elastic member 19 uses a spring, is installed on the outer periphery between the locking jaw 13 of the ferrule flange 11 and the washer 18, and is tensioned / compressed according to the position of the washer 18 have a shape

The main optical fiber (B) is fused with the optical fiber (A) for ferrule of the ferrule part (10) described above. It is an optical fiber that is fused through

In the present invention, the main optical fiber (B) has a single layer of outer sheath (C') (for Tight Buffer Fiber, Tight Buffer Coated Fiber is formed on the outside of the bare fiber), and the outer sheaths (C', C'') ) is two layers (for Fiber Cord, Tight Buffer Coated Fiber and Optical Fiber Cord are sequentially formed on the outside of the Bare Fiber), the parts that surround and protect the main optical fiber (B) are different.

In the first case, the sheath C' of the main optical fiber B is a single layer, and includes a fusion sleeve 20, a coupling nut 30, and a boot 50.

The fusion sleeve 20 protects the fused portion of the optical fiber for ferrule (A) and the main optical fiber (B) exposed to the outside, and is contracted when heated by the fusion device, and the optical fiber for ferrule (A) and the main optical fiber ( B) It is to prevent the bending of mutually fused parts.

The coupling nut 30 is screwed to the outer circumference of the other end of the ferrule flange 11, passes through the fusion sleeve 20, is fastened to the other end of the ferrule flange 11, and the coupling nut is caught on the outer circumference of the other end It is a part forming the jaw 31, and the boot 50 has a shape in which the main optical fiber B passes through the inside and the diameter gradually decreases in the longitudinal direction, the coupling nut of the coupling nut 30 It is a part where one end is fitted to the locking jaw 31.

In the second case, the sheaths C' and C'' of the main optical fiber B are two layers, and the fusion sleeve 20, the coupling nut 30, the screw cap 40, and the boot 50 ).

As in the first case described above, the fusion sleeve 20 is used to protect the fused portion of the exposed ferrule optical fiber A and the main optical fiber B, and the coupling nut 30 is a ferrule In order to be fastened with the flange 11, a thread corresponding to the thread of the other end of the ferrule flange 11 is once formed on the inner periphery, the fusion sleeve 20 is penetrated in the center, and the thread is formed on the outer periphery of the other end. do.

The screw cap 40 is screwed to the outer periphery of the other end of the coupling nut 30 and has a shape in which a diameter decreases in multiple stages in the longitudinal direction. The boot 50 is a part through which the main optical fiber B passes through and is fitted and fastened to the outer periphery of the other end of the screw cap 40.

The protection tube 60 protects the outer periphery of the main optical fiber B inserted into the screw cap 40 and the boot 50 described above, and one end spans the inner periphery of the screw cap 40 so that the screw cap ( 40) to be prevented from being removed. To this end, a removal prevention piece 61 is formed on the outer periphery of one end of the protection tube 60 spanning the inner periphery of the screw cap 40.

The bayonet coupling 70 has a hollow inside and has a through-center shape, and a protruding portion 10a having a central penetration is formed at an inner stop, and a ferrule flange ( 11) is accommodated, so that the washer 18 portion of the ferrule flange 11 does not fall to the rear end of the engaging portion 10a, and the other side of the engaging portion 10a is screwed with the ferrule flange 11 Coupling The nut 30 is inserted and screwed into the ferrule flange 11. In addition, a 'L' shaped fixing groove 71 is formed on the outer periphery of the bayonet coupling 70.

The protective cap 80 is a part fastened to the end of the ferrule 15 for protection.

The assembly tool 90 has the above-described protection cap 80 penetrated therein in the longitudinal direction, and a slit groove 91 inserted in correspondence with the locking protrusion 12 is formed on one side to position the ferrule flange 11 is aligned, and the elastic member 19 is pressed toward the ferrule flange 11 so that it is compressed, so that the fixing protrusion 92 on the outer periphery follows the shape of the fixing groove 71 of the bayonet coupling 70, while corresponding It is the part that makes it rotate.

As described above, although the present invention has been described by the limited embodiments and drawings, the present invention is not limited thereto, and the technical spirit of the present invention and the following by those skilled in the art to which the present invention belongs Of course, various modifications and changes are possible within the scope of equivalents of the claims to be described.

10: ferrule part 10a: bridging part
11: ferrule flange 12: snag
13: locking jaw 14: screw thread
15: ferrule 16: groove
17: C-ring 18: washer
19: elastic member 20: fusion sleeve
30: coupling nut 31: coupling nut locking jaw
40: screw cap 50: boot
60: protective tube 61: removal prevention piece
70: Bayonet Coupling
71: fixing groove 80: protective cap
90: assembly tool 91: slit groove
92: fixed protrusion
A: Fiber for ferrule B: Main fiber
C', C'': outer skin

Claims (4)

In the field assembly type fusion spliced optical fiber connector,
A ferrule flange 11 through which the center is penetrated in the longitudinal direction, a locking protrusion 13 protruding the locking protrusion 12 is formed on the outer periphery at one end, and a screw thread is formed at the other end;
an optical fiber for a ferrule (A) disposed inside the ferrule flange 11 in a longitudinal direction and having both ends exposed to the outside from which the coating is peeled;
A ferrule 15 in which one end of the optical fiber A for the ferrule is inserted and fastened to one side of the ferrule flange 11;
A C ring 17 fastened to the outer periphery of the other end of the ferrule flange 11;
a washer installed on the outer periphery of the ferrule flange 11 and whose position is interrupted by the C-ring 17;
an elastic member 19 installed on the outer periphery between the locking shoulder 13 of the ferrule flange 11 and the washer, and tensioned/compressed according to the position of the washer;
The ferrule part 10 made of is assembled integrally in advance and provided to the site,
When assembling the optical fiber connector in the field, by screwing the ferrule flange 11 and the coupling nut 30, the assembly process is easy with simplified parts, and there is no problem in the assembly sequence.
A straddling portion 10a is formed at the inner stop, so that the ferrule flange 11 is accommodated on one side of the straddling portion 10a so that the washer is strung, and the other side of the straddling portion 10a is screwed with the ferrule flange 11 A bayonet coupling (70) in which the coupling nut (30) is positioned and a fixing groove (71) is formed on the outer periphery;
A protective cap 80 fastened to the end of the ferrule 15 for protection;
The protective cap 80 is penetrated in the longitudinal direction inside, and a slit groove 91 is formed on one side to be inserted correspondingly to the locking protrusion 12 so that the position of the ferrule flange 11 is aligned, and the elastic member ( 19) is pressed toward the ferrule flange 11 so as to be compressed, so that the fixing protrusion 92 on the outer periphery is coupled to the fixing groove 71 of the bayonet coupling 70 in correspondence with the assembly tool 90; Field assembly type fusion spliced optical fiber connector, characterized in that further provided.
According to claim 1,
When the optical fiber (A) for the ferrule is fused with the main optical fiber (B) having a single sheath (C′),
The main optical fiber (B) is
a fusion sleeve 20 that protects a fusion portion between the exposed optical fiber for ferrule (A) and the main optical fiber (B);
It is screwed to the outer circumference of the other end of the ferrule flange 11, penetrates the fusion sleeve 20 and is fastened to the other end of the ferrule flange 11, and forms a coupling nut locking jaw 31 on the outer circumference of the other end coupling nut 30;
a boot 50 through which the main optical fiber B passes through and one end of which is fitted into the coupling nut locking jaw 31 of the coupling nut 30;
Field assembly type fusion spliced optical fiber connector, characterized in that protected through.
According to claim 1,
When the optical fiber (A) for the ferrule is fused with the main optical fiber (B) having two layers of sheaths (C', C''),
The main optical fiber (B) is
a fusion sleeve 20 that protects the fusion portion between the exposed optical fiber for ferrule (A) and the main optical fiber (B);
a coupling nut 30 that penetrates the fusion sleeve 20 and is screwed to the other end of the ferrule flange 11 and forms a thread on the outer periphery of the other end;
A screw cap 40 screwed to the outer periphery of the other end of the coupling nut 30 and having a diameter reduced in multiple stages in the longitudinal direction;
a boot 50 through which the main optical fiber B passes through and is fitted to the outer periphery of the other end of the screw cap 40;
Protects the outer periphery of the main optical fiber (B) inserted into the screw cap 40 and the boot 50, and one end spans the inner periphery of the screw cap 40 to prevent removal of the screw cap 40 protection tube 60;
Field assembly type fusion spliced optical fiber connector, characterized in that protected through.
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