KR102305131B1 - A fiber optic Breakout kit including Fiber cord protection unit - Google Patents

Abstract

The present invention relates to a multi-core optical fiber cord protection unit and a breakout kit including the same. More specifically, it relates to a multi-core optical fiber cord protection unit that provides a field-assembled multi-core optical fiber cord protection unit that can protect a multi-core optical fiber fusion part, and at the same time composes a factory pre-assembled fiber optic breakout assembly and multi-core connection type optical connector kit into a single kit to reduce construction time on site, and a breakout kit including the same.

Description

A fiber optic breakout kit including Fiber cord protection unit

The present invention fusion splices a factory-assembled fiber optic branch assembly and a multicore splice type optical connector kit with a multicore optical fiber in the field, and the fusion spliced portion can be protected through a multicore fiber optic cord protection unit that is assembled and used in the field. Accordingly, it relates to a multi-core fiber optic cord protection unit and a branch kit including the same, enabling quick construction.

In the modern information society, the role of communication networks occupies a very important part. In particular, as network communication such as the Internet develops and transmits a large amount of data such as voice or video, an increase in information throughput and processing speed is required. The expansion of the communication network is urgently required.

In order to satisfy this demand, an optical cable is used instead of the existing coaxial cable as a way to process large amounts of information at high speed, and the use of optical cables is rapidly increasing.

Optical communication refers to communication that transmits and receives light signals through optical fibers composed of a core of inner glass with a high refractive index and a cladding of outer glass with a low refractive index. Optical fiber used for optical communication has no interference or crosstalk by external electromagnetic waves, so it is difficult to eavesdrop on it, it is small and lightweight, and it is strong in bending. Have. An optical cable is a cable made by bundling these optical fibers into several strands, and a large amount of information can be exchanged simultaneously through the optical cable.

The multi-channel optical connector is a multi-fiber push-on (MPO) connector at both ends. It consists of an MPO patch cord consisting of 12 optical fibers in one connector and a hybrid patch cord of an individual connector type in which the other end is divided for each channel. include

However, if the multi-channel optical connector in the form of a finished product is used in the past, if the total length of the optical cable and connector installation site such as a data center is shorter than the total length of the finished optical connector transported to the site, the installation itself I couldn't do it, so I had to retrieve the installed one and reinstall it with another one,

If the total length of the optical connector assembly of the finished product is longer than the installation length on the site, a storage device for storing the finished product had to be installed because the woman's dress remains.

As a result, the operator prepares an optical cable of a longer length overall than the previously known installation length of the site, but eventually uses a portion of the woman's clothing that does not need to be used, so there is a problem in that the installation cost is increased.

However, if a field-assembled optical connector and an optical fiber branch assembly are used to solve this problem, it is possible to construct the optical cable or optical cord wire without remaining female, but there is a problem that it takes a lot of time.

Republic of Korea Patent Publication No. 10-1895043 (Registered on August 29, 2018)

The present invention has been devised to solve the above problems, and an object of the present invention is to provide an optical fiber branch assembly and a multi-core splice type optical connector kit after pre-fabrication in a factory, and to protect the multi-core optical fiber fusion splicer in the field. It is to provide a multi-core fiber-optic cord protection unit and a branch kit including the same, which can protect the fusion spliced part by assembling only a field-assembled multi-core optical fiber cord protection unit.

Other objects and advantages of the present invention will be set forth below and will be learned by way of example of the present invention. Further, the objects and advantages of the present invention may be realized by means and combinations indicated in the claims.

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

The fusion sleeve 10 is covered with the fusion portion of the multi-core optical fiber (F) that is fusion spliced in the form of a flat ribbon after the outer skin is peeled off, and is used to protect the fusion portion;

A fitting space 21 to which the fusion sleeve 10 can be mounted is formed therein, and it is composed of upper and lower covers 30 and 20 and is fastened and fixed in a state separated from each other, and is fused on both sides of the multi-core optical fiber. (F) the main cover 40 to be exposed to the outside;

a side cover 50 that is fastened and fixed to both sides of the main cover 40 and is installed to extend, and allows the multi-core optical fiber F to pass therethrough in the longitudinal direction;

a screw cap assembly 60 that is screwed to both sides of the side cover 50 after aligning the outer skin of the Kevlar and the optical cable on the outside of the side cover 50; It is characterized in that it is assembled and used in the field to protect the fusion part.

As described above, in the present invention, a pre-assembled fiber optic branch assembly and a multi-core splice type optical connector kit are fusion spliced to a multi-core optical fiber in the field, and the fusion spliced portion is protected by assembling a unit for protecting the multi-core fiber optic cord in the field. By doing so, there is an effect that enables rapid construction of multi-core optical fiber fusion splicing and protection of the fusion splicing part.

In addition, according to the present invention, a multi-core optical fiber cord protection unit, an optical fiber branch assembly, and a multi-core connection type optical connector kit are configured as a single branch kit, so that it is easy to carry and has the effect of easy transport and transport.

1 is a view of an embodiment showing a multi-core optical fiber cord protection unit according to the present invention.
Figure 2 is an exploded perspective view of Figure 1;
Fig. 3 is a cross-sectional view of Fig. 1;
4A and 4B are views of an assembly method of a multi-core optical fiber cord protection unit according to the present invention.
5 is a block diagram showing a branch kit including a multi-core optical fiber cord protection unit according to the present invention.
6 is a view showing a first embodiment of a branch kit including a multi-core optical fiber cord protection unit according to the present invention.
7 is a view showing a second embodiment of a branch kit including a multi-core optical fiber cord protection unit according to the present invention.

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

In order to achieve the above object, the present invention has the following features.

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 the present specification and claims should not be construed as being limited to conventional or dictionary meanings, and the inventor should properly understand the concept of the term in order to best describe his invention. Based on the principle that it can be defined, it should be interpreted as meaning and concept consistent with the technical idea of the present invention.

Therefore, the configuration shown in the embodiments and drawings described in the present specification is only the most preferred embodiment of the present invention and does not represent all of the technical spirit of the present invention, so at the time of the present application, various It should be understood that there may be equivalents and variations.

Hereinafter, a unit for protecting a multi-core optical fiber cord and a branch kit including the same according to a preferred embodiment of the present invention will be described in detail with reference to FIGS. 1 to 7 .

The multi-core optical fiber cord protection unit according to the present invention includes a fusion sleeve 10 , a main cover 40 , a side cover 50 , and a screw cap assembly 60 .

The fusion sleeve 10 is covered with a fusion part of a multi-core optical fiber (F) that is fusion spliced in the form of a flat ribbon after the outer skin is peeled off, and is used to protect the fusion splicing part, which is the fusion splicing part.

The main cover 40 has a fitting space 21 in which the aforementioned fusion sleeve 10 can be mounted correspondingly is formed therein, and is composed of upper and lower covers 30 and 20, and is fastened and fixed in a state separated from each other. , so that the fused multi-core optical fiber F is exposed to the outside on both sides.

The upper and lower covers 30 and 20 have a cross-sectional shape of a semicircle of a shape corresponding to each other in order to form a cylindrical shape of a circular cross-section with both ends open and the interior empty in the longitudinal direction when coupled to each other. Looking at the fastening structure in which the upper and lower covers 30 and 20 are fastened to form one body,

A plurality of fitting pieces 22 protruding toward the upper cover 30 from both sides of the fitting space 21 of the lower cover 20, and the fitting pieces 22, penetrate through the upper cover 30 so that the fitting pieces 22 are coupled to each other. Through the formed insertion portion 31, the fastening path between the fitting piece 22 and the insertion portion 31 so that the upper and lower covers 30 and 20 can be fastened and fixed, and also,

A plurality of hooking pieces 32 in the form of hooks protruding from both sides of the top cover 30 toward the bottom cover 20, and the plurality of hooking pieces 32 correspond to each other, so that the lower cover 20 ) through the locking grooves 25 formed on both sides of the outer periphery, so that the upper and lower covers 30 and 20 can be fastened and fixed more reliably.

In addition, the support piece 23 and the fixing groove 24 are further formed in the main cover 40, so that the multi-core optical fiber F can be fixedly supported and fastened to the side cover 50 to be described later can be ensured. The support piece 23 is formed to protrude in the vertical direction on both inner periphery of both sides of the above-described lower cover 20, and is a plate material for supporting the multi-core optical fiber (F).

The fixing grooves 24 are formed on both sides of the upper and lower covers 30 and 20, on one side of the support piece 23 (more specifically, on the upper and lower covers 30 and 20) than the support piece 23 forming portion. It is recessed in the form of a ring in the outer part) so that the fastening ring 53 formed on the outer periphery of the side cover 50 is mounted and fixed.

The side cover 50 is fastened and fixed to both sides of the above-described main cover 40 and extended, so that the multi-core optical fiber F is penetrated therein in the longitudinal direction.

This side cover 50 has a cylindrical shape with a circular cross-section, the inside of which is empty in the longitudinal direction.

In addition, the rotation fastening part 51 formed on the outer periphery is formed so that the screw cap assembly 60 can be screwed, and one end of the rotation fastening part 51 (more specifically, the main cover described above) 40) extending in the form of a hemispherical cross-sectional shape of '∩' with an open lower end, and placed on the support pieces 23 protruding vertically on both sides of the lower cover 20, the multi-core optical fiber ( F) to further form an extension 52 for fixing the position.

The screw cap assembly 60 is to first align the outer skin of the Kevlar and optical cable on the outside of the above-described side cover 50, and then are screwed to both sides of the outer periphery of the side cover 50, respectively.

Of course, it will be natural that the multi-core optical fiber F penetrates in the inner longitudinal direction, and has a circular cross-section whose diameter gradually becomes narrower as it moves away from the side cover 50 .

The configuration of the screw cap assembly 60 for this purpose has a structure that is sequentially fastened in the order of a screw cap 61 , a fiber cord boot 62 , and a protection tube 63 . .

In addition, the coupling sequence of the multi-core optical fiber cord protection unit 100 having the above structure will be described with reference to FIG. 4 .

1. After fusion splicing two ribbon-type multicore optical fibers (F) to be fusion spliced through a separate portable splicing device or various splicing means, the splicing sleeve 10 is covered and protected After making it possible

2. Insert the fusion sleeve 10 into the fitting space 21 of the lower cover 20 constituting the main cover 40 so as to correspond, and both sides of the multi-core optical fiber F are both sides of the lower cover 20 in the longitudinal direction. Assembled to protrude,

3. In the fixing grooves 24 formed on both sides of the lower cover 20, one side of the fastening ring 53 of the side cover 50 is fixed while correspondingly mounted,

4. The upper cover 30 is fastened to correspond to the upper end of the lower cover 20. At this time, the fitting piece 22 of the lower cover is fastened to the insertion part 31 of the upper cover 30, and the upper cover ( 30) while the locking piece 32 is fastened to the locking groove 25 of the lower cover 20, the upper and lower covers 30, 20 are securely coupled and fixed to each other.

5. After arranging the exterior of the side cover (50) of Kevlar and the optical cable built into the optical cable,

6. Finally, the screw cap assembly 60 (Screw cap 61) is screwed together at both outer ends of the side cover 50 to complete the assembly.

In the present invention, together with the multi-core optical fiber cord protection unit 100 having the above structure, the optical fiber branch assembly 200 and the multi-core connection type optical connector kit 300 are configured as a single branch kit 400, Enables fast fiber optic connection.

As a first example for this

In order to protect the fusion splicing between the multi-core optical fibers to be fused (F), a multi-core optical fiber cord protection unit 100 assembled on the fusion splicing unit in the field; an optical fiber branch assembly 200 that is provided in a pre-assembled state at the factory and is connected to one end of the multi-core cord line 500; A multi-core connection-type optical connector kit 300 configured by being divided into a plurality of components so as to be assembled into a multi-core connection type optical connector 310 in the field; The multi-core fiber optic cord protection unit 100 can be mounted, the inside of the branch kit 400 is divided into a plurality of spaces 410; is composed of; to enable the installation of

Alternatively, in order to protect the fusion splicing between the multi-core optical fibers (F) to be fused, a multi-core optical fiber cord protection unit 100 assembled to the fusion splicing unit in the field; an optical fiber branch assembly 200 that is provided in a pre-assembled state at the factory and is connected to one end of the multi-core cord line 500; a branch kit 400 whose interior is divided into a plurality of spaces 410 so that the multi-core optical fiber cord protection unit 100 can be mounted; It enables quick optical cable connection in the field.

That is, as described above, the multi-core optical fiber cord protection unit 100 is a part assembled in a fusion splicing part in the field in order to protect the fusion splicing part between the multi-core optical fibers F to be fusion spliced,

The optical fiber branch assembly 200 (branched and connected to multiple uses) and the multi-core connection type optical connector kit 300 are each provided in a pre-assembled state (pre-assembled) at the factory, and are connected and installed at one end of each optical fiber will become

The branch kit 400 is provided with a multi-core optical fiber cord protection unit 100, an optical fiber branch assembly 200, and a multi-core connection type optical connector kit 300, and is assembled on site, and the multi-core optical fiber cord protection unit 100 ), the optical fiber branch assembly 200, and the multi-core connection type optical connector kit 300 to be mounted, the inside of which is divided into a plurality of spaces 410 to serve as an openable and openable transport box.

In the case of the multi-core connection type optical connector kit 300, as shown in FIG. 6, a cover is provided so that it can be opened and closed, and a plurality of old parts are partitioned and arranged in the inner space of the multi-core connection type optical connector kit 300 It is configured in the form of a single multi-core connection type optical connector 310 to be assembled and used in the field, thereby enabling rapid optical cable connection and installation of the multi-core connection type optical connector 310 .

In addition, in the case of the multi-core connection type optical connector kit 300, as shown in FIG. 7, the multi-core connection type optical connector 310 is provided in the branch kit 400 in a pre-assembled form, or the branch kit ( 400) is provided with only the multi-core optical fiber cord protection unit 100 and the optical fiber branch assembly 200 to enable rapid optical cable connection and installation of the multi-core optical connector 310 in the field.

In other words, in order to protect the fusion splicing between the multi-core optical fibers F to be fused, the multi-core optical fiber cord protection unit 100 assembled at the fusion splicing part in the field is provided in a pre-assembled state at the factory, and the multi-core cord The optical fiber branch assembly 200 connected to one end of the line 500, the multi-core connection type optical connector 310 and the multi-core cord line 500 are connected and connected in the field.

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

10: fusion sleeve 20: bottom cover
21: fitting space 22: fitting piece
23: support piece 24: fixed groove
25: locking groove 30: top cover
31: insertion part 32: catch piece
40: main cover 50: side cover
51: rotation fastening part 52: extension part
53: fastening ring 60: screw cap assembly
61: screw cap 62: boot
63: protection tube 100: multi-core fiber optic cord protection unit
200: fiber optic branch assembly 300: multi-core splice type optical connector kit
310: multi-core connection type optical connector 400: branch kit
500: cord line
410: space
F: multi-core fiber

Claims (7)

The fusion sleeve 10 is covered with the fusion part of the multi-core optical fiber (F), which is fusion spliced in the form of a flat ribbon after the skin is peeled off, and is used to protect the fusion part;
A fitting space 21 to which the fusion sleeve 10 can be mounted is formed therein, and it is composed of upper and lower covers 30 and 20 and is fastened and fixed in a state of being separated from each other, and fused to both sides of the multi-core optical fiber. (F) the main cover 40 to be exposed to the outside;
a side cover 50 that is fastened and fixed to both sides of the main cover 40 and is installed to extend, and allows the multi-core optical fiber F to pass therethrough in the longitudinal direction;
a screw cap assembly 60 that is screwed to both sides of the side cover 50 after aligning the outer skin of the Kevlar and the optical cable on the outside of the side cover 50;
It is composed of, and is assembled and used in the field to protect the fusion part,
The main cover 40 is
Fitting pieces 22 protruding from both sides of the fitting space 21 of the lower cover 20 toward the upper cover 30;
Insertion part 31 which is formed through the top cover 30 so that the fitting piece 22 is fastened correspondingly;
A plurality of hook-shaped hook-shaped pieces (32) protruding from both sides of the top cover (30) toward the bottom cover (20);
Locking grooves 25 formed on both sides of the outer periphery of the lower cover 20 so that the plurality of locking pieces 32 correspond and can be hung; is composed of
The main cover 40 is
a support piece 23 protruding vertically from both inner periphery of the lower cover 20 to support the multi-core optical fiber (F);
On both sides of the upper and lower covers 30 and 20, a ring-shaped depression is formed on one side of the support piece 23, and a fastening ring 53 formed at one end of the side cover 50 on the outer periphery is mounted correspondingly. and a fixing groove 24 to be fixed; includes,
The side cover 50 is
a rotation fastening part 51 formed on an outer periphery of the screw cap assembly 60 to be screwed;
It is formed to extend in a hemispherical shape from one end of the rotation fastening part 51 and is placed on the support pieces 23 protruding vertically on both sides of the lower cover 20 to fix the position of the multi-core optical fiber (F). extension 52; Multi-core optical fiber cord protection unit comprising a.
The multi-core optical fiber cord protection unit 100 of claim 1;
an optical fiber branch assembly 200 that is provided in a pre-assembled state at the factory and is connected to one end of the multi-core cord line 500;
a branch kit 400 in which the inside is divided into a plurality of spaces 410 so that the multi-core optical fiber cord protection unit 100 can be mounted;
and enables rapid multi-core optical fiber connection and installation of multi-core optical connector 310 in the field,
The branch kit 400 has
A multi-core connection-type optical connector kit 300 configured by being divided into a plurality of components so as to be assembled into a multi-core connection type optical connector 310 in the field; Branch kit including a multi-core optical fiber cord protection unit, characterized in that it is further provided.
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