KR101080374B1 - Divergencing set for optical fiber drop cable - Google Patents

Abstract

The present invention relates to a branching set for an incoming optical cable that stably connects the optical cable and the branched optical core so that the bending and breaking of the branched optical core is prevented when the incoming optical cable is branched into a plurality of optical cores during FTTH construction. will be.

The present invention provides an adapter 100 having a single inlet into which the optical fiber for inlet 10 is fitted and a plurality of outlets through which branch optical cores 11 and 12 inside the optical fiber for branching branched from the optical fiber for inlet pull out;

The branched optical core tubes 11 and 12 branched through the outlets of the adapter 100 pass through the inside of the adapter 100 and are inserted into and coupled to the outlet 120 of the adapter while passing through the branched optical cores. 200; And

It is configured to include a heat shrinkable protective tube 300 is inserted into the outside of the branch optical core tube 200 to heat-shrink during the heating process to seal the branched portion.

Fiber Optic Cable, Fiber Core, Branch, Adapter, FTTH

Description

Diving set for optical fiber drop cable

The present invention relates to a branching set for an incoming optical cable that stably connects the optical cable and the branched optical core so that the bending and breaking of the branched optical core is prevented when the incoming optical cable is branched into a plurality of optical cores during FTTH construction. will be.

In general, an optical communication system is widely used as a transmission medium for increasing communication capacity and transmitting a large amount of data, and in recent years, an FTTH (Fiber to the Home) network, in which an optical cable is connected to each home, has been realized.

FTTH can be divided into AON (Active Optical Network) and PON (Passive Optical Network) according to the method of construction. The PON format which branches and distributes is preferred. At this time, the optical cable used is largely divided into outdoor cable installed outdoors and indoor cable connected from the indoor terminal box to the equipment and a cable for entering the outdoor terminal box from the outdoor junction box.

Of these, the incoming optical cable is a cable connected to the terminal box of the indoor from the junction box of the outdoor cable is used a thin optical cable is thinner than the outdoor cable. Such a fiber-optic cable has a single or double-core branched fiber cores inside, and the branched fiber cores must be branched at a certain point because they must be connected to each generation or one-to-one correspondence with connection terminals of the premises terminal box.

Therefore, the branching of the conventional incoming optical cable was made in a separate protective enclosure for the protection of the branch part which is very susceptible to impact, and this protective enclosure had to be fixed depending on a stable support, and thus many restrictions were placed on the installation site. Due to these limitations, the conventional branching of the incoming optical cable is made in an indoor terminal box or an outdoor terminal box.

Since the conventional optical fiber branching is performed only at a specific place such as a terminal box, it is inconvenient in the branching operation of the optical cable, and it is not necessary to branch at the optimum point and wastes the optical fiber for incoming because it is necessary to extend the optical fiber unnecessarily to a specific place. Has a serious problem.

It is an object of the present invention to provide a set of incoming optical cable branches in which the branching of the incoming optical cable is made simple and optimal at the optimum point and the branching point is secured.

In order to achieve the above object, the incoming optical cable branch set of the present invention is an adapter having an inlet to which the incoming optical cable is fitted and a plurality of outlets through which the branch optical cores inside the incoming optical cable branched from the incoming optical cable exit; Branched optical core tube exiting each outlet of the adapter passes through the inside and the branched optical core tube is inserted into the adapter and coupled to the outlet of the adapter while passing through the branching optical core, and the heating process is inserted into the outside of the branching optical core tube It is characterized in that it comprises a heat shrinkable protective tube for sealing the branched portion during heat shrink.

According to the present invention configured as described above, since it is possible to branch the optical cable for entry immediately at the site without regard to the place, the branching operation is very simple as compared with the conventional art, and there is an effect of preventing unnecessary waste of the optical cable for entry.

The features and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments with reference to the accompanying drawings. Prior to this, the terms or words used in the present specification and claims are defined in the technical spirit of the present invention on the basis of the principle that the inventor can appropriately define the concept of the term in order to explain his invention in the best way. It must be interpreted to mean meanings and concepts.

As shown in FIG. 1, the present invention provides a single inlet into which the optical fiber cable 10 is inserted and branch optical cores 11 and 12 inside the optical fiber cable 10 branched from the optical fiber cable 10. The adapter 100 having a plurality of exits and the branched optical cores 11 and 12 exiting the outlets of the adapter 100 pass through the adapter 100 and exit the branched optical cores 11 and 12. Branch optical core tube 200 is inserted into the outlet 120 of the adapter 100 in the state passed through, and the heat shrinkability to seal the branching portion while the heat shrink during the heating process is inserted into the outer side of the branch optical core tube 200 It consists of a protective tube (300).

As shown in Figures 2 and 3, the adapter 100 is made of a soft synthetic resin or rubber material having a self-elasticity so as to flexibly protect the branching portion of the optical fiber cable 10 for incoming from the external impact do. The adapter 100 has a single inlet 110 into which the incoming optical cable 10 is fitted at both sides, and the branch optical core 11 inside the incoming optical cable 10 branched from the incoming optical cable 10. 12) have a plurality of outlets 120 and 120 through which they exit. The inlet 110 and the outlet 120, 120 should be located on the same horizontal plane so that the branch is not bent or bent. In this embodiment, the adapter 100 having two outlets is illustrated and described by way of example, and accordingly, an incoming optical cable 10 having two branched optical cores 11 and 12 is incorporated.

Meanwhile, the inlet 110 and the outlet 120 of the adapter 100 are tapered to narrow toward the center of the adapter 100 so that the inlet optical cable 10 or the branch optical core tube 200 can be easily fitted. It is preferable.

In addition, the adapter 100 may further have a first branch optical core through hole 130 extending from the inlet 110 of the adapter 100. The first branch optical core through-hole 130 has a diameter smaller than the outer diameter of the incoming optical cable 10 and larger than the outer diameter of the branch optical cores 11 and 12. In this case, the incoming optical cable 10 fitted from the inlet 110 of the adapter 100 interferes with the first branch optical core through-hole 130 having a relatively small diameter and enters into the adapter 100. Entry is restricted. Therefore, the worker can always insert the inlet optical cable 10 to the inlet 110 of the adapter 100 only a certain length, the inlet in the process of fitting the inlet optical cable 10 to the inlet 110 of the adapter 100 By detecting that the optical fiber cable 10 interferes with the first branch optical core through-hole 130, it can be seen that the fitting operation of the optical fiber cable 10 is completed.

In addition, the adapter 100 may further have a single guide hole 140 extending inclinedly extending from the first branch optical core through-hole 130 to the outlet 120 of the adapter 100. The guide hole 140 guides the branch optical cores 11 and 12 passing through the first branch optical core passage hole 130 to naturally reach the outlet 120 of the adapter 100.

The outlet 142 of the guide hole 140 has a smaller diameter than the branch optical core tube 200 so as to be stepped with respect to each outlet 120 of the adapter 100. That is, the outlet 142 of the guide hole 140 is in the form of a long hole in communication with the outlets 120 of all the adapters 100, and the short side diameter of the long hole is smaller than the diameter of the branch light core tube 200. Therefore, the outlet 142 of the guide hole 140 is formed stepped with respect to all the outlets of the adapter 100. As such, when the outlet 142 of the guide hole 140 is stepped with respect to all the outlets 120 of the adapter 100, the branched optical core tube 200 fitted through the outlet 120 of the adapter 100 is provided. Interfering with the guide hole 140 is restricted entry into the adapter 100. Therefore, the operator can always insert the branch optical core tube 200 into the adapter 100 outlet only by a certain length, and the branch optical core tube 200 in the process of inserting the branch optical core tube 200 into the adapter 100 outlet. By detecting the interference of the guide hole 140, it can be seen that the fitting operation of the branch optical core tube 200 is completed well.

In addition, the inlet 141 of the guide hole 140 has a diameter smaller than that of the first branch optical core through-hole 130 so as to be stepped with the first branch optical core through-hole 130. This is to enable the adapter 100 to be used as a combined diameter optical cable 10 for the small. That is, some of the incoming optical cables 10 include an incoming optical cable 10 having a diameter enough to be fitted into the first branch optical core through-hole 130. In this case, the incoming optical cable inserted from the inlet of the adapter 100 is provided. 10 interferes with the inlet 141 of the guide hole 140 having a diameter smaller than that of the first branch optical core through-hole 130, thereby restricting entry into the adapter 100. Therefore, the operator can always insert the optical fiber 10 for the introduction only to the inlet of the adapter 100 by a certain length, the optical fiber 10 for the introduction in the process of inserting the optical fiber 10 for the adapter 100 to the inlet of the adapter 100 By detecting interference with the inlet 141 of the hole 140, it can be seen that the fitting operation of the incoming optical cable 10 is completed well.

On the other hand, as shown in Figure 4, the first branch optical core through hole 130 and the guide hole 140 is smaller than the outer diameter of the optical fiber 10 for the incoming and the diameter of the branch optical core (11, 12) It is preferable to be connected through the second branch optical core through-hole 150 larger than the outer diameter. This is to prepare for the specification of the small diameter of the incoming optical cable 10 of the incoming optical cable (10). In this case, the incoming optical cable 10 is very thin in diameter, so even if interference with the guide hole 140 occurs during the fitting operation to the inlet of the adapter 100, the operator's mistake is directed to the guide hole 140. Can be entered. However, when the second branch optical core through hole 150 is formed, the incoming optical cable 10 exiting the first branch optical core through hole 130 passes through the narrow second branch optical core through hole 150. Further entry is restricted by surface friction with the second branch optical core through hole 150 in the process. Therefore, when the optical fiber 10 for the inlet of the small diameter is fitted into the outlet 120 of the adapter 100, an accident of entering the guide hole 140 is prevented.

The branched optical core tube 200 is a tube having a hollow portion for allowing the branched optical cores 11 and 12 exiting the outlets 120 of the adapter 100 to pass therethrough, and the optical fiber for pulling in 10 It is made of the same material as the outer shell of). The divergent optical core tube 200 is fitted to the outlet 120 of the adapter 100 in a state where the divergent optical cores 11 and 12 pass through the hollow portion.

The heat shrinkable protective tube 300 is fitted to the outside of the branch optical core tube 200 and has a sufficient length to wrap a part of the incoming optical cable 10 and the branch optical core tube 200. A heat adhesive is applied to the inner surface of the heat shrinkable protective tube 300 to seal the branched portion while heat shrinking during the heating process.

Meanwhile, the pulling optical cable 10 and the branch optical core tube 200 may be fixed together with the adapter 100 through an adhesive tape 400 so as not to be separated from the adapter 100. This is because, in the heat shrinkage treatment process of the heat shrinkable protective tube 300, the inlet optical cable 10 and the branch optical core tube 200 which are only inserted into the inlet 110 and the outlet 120 of the adapter 100 are adapters. This is to enhance the convenience of the work so as not to be separated from the (100).

Referring to the method of using the optical fiber branch set for the incoming of the present invention configured as described above is as follows.

First, as shown in FIG. 5, in a state in which the heat shrinkable protective tube 300 is pre-inserted into the optical fiber 10 for inlet, the outer side sheath of the optical fiber 10 for inlet is stripped to a predetermined length so that the optical fiber for the optical fiber 10 may be removed. ) To expose the branch optical cores 11 and 12 inside.

And, as shown in Figure 6, through the inlet 110 of the adapter 100, the branch optical cores (11, 12) are inserted at once. Then, each branch optical core (11, 12) is guided by the guide hole 140 to exit through each outlet (120, 120) of the adapter (100). When the branch optical cores 11 and 12 exit from the outlet 120 of the adapter 100, the inlet of the adapter 100 until the incoming optical cable 10 interferes with the entrance of the first branch optical core through hole or the guide hole. Into (110). The incoming optical cable 10 does not enter any more while interfering with the entrance of the first branch optical core through-hole or guide hole according to the difference in diameter. When the incoming optical cable 10 is fully inserted into the inlet 110 of the adapter 100, the ends of the branched optical cores 11 and 12 exiting the outlet 120 of the adapter 100 are branched core tube 200. ) Into the

As shown in FIG. 7, when the branching optical cores 11 and 12 are both fitted into the branching optical core tube 200, the adapter 100 may be inserted into the branching optical core tube 200 until it interferes with the exit of the guide groove. In the outlet 120). The branched optical core tube 200 is no longer entered as it interferes with the exit of the guide hole.

In this state, as shown in Figure 8, using the adhesive tape 400, the optical fiber 10, the adapter 100 and the branch optical core tube 200 is fixed integrally, and then pre-inserted heat shrinkage Cover the protective tube 300 to the branch. And heat is applied to the heat shrinkable protective tube 300 to shrink the heat shrinkable protective tube (300). In this way, as shown in Figure 1, while the branch is firmly sealed, the external shock or moisture inflow is protected in a completely blocked state.

As described above, preferred embodiments of the present invention are described above with reference to the drawings, but the present invention is not limited to the above-described embodiments, and those skilled in the art to which the present invention pertains can make modifications without departing from the spirit of the present invention. Possible, such modifications will fall within the scope of the invention.

1 is a perspective view of a state of use of the optical fiber branch set for the pulling in accordance with the present invention.

Figure 2 is a cross-sectional view of the adapter constituting the set of branching optical cable according to the present invention.

Figure 3 is a side view of the outlet side of the adapter constituting the set of branching optical cable according to the present invention.

Figure 4 is a cross-sectional view according to another embodiment of the adapter constituting the set of incoming optical cable branch in accordance with the present invention.

Fig. 5 is a state diagram showing the use of the branch set of the optical fiber for pulling according to the present invention, showing a state in which the heat shrinkable protective tube is inserted into the optical fiber for the pulling in advance.

6 is a state diagram of the use of the optical fiber branch set for the pulling in accordance with the present invention, showing a state in which the optical fiber for insertion is inserted into the inlet of the adapter.

7 is a state diagram of the use of the optical fiber branch set for the pull-out according to the present invention, the branch optical core tube is inserted into the outlet of the adapter.

8 is a view showing a state of use of the optical fiber branch set for pulling in accordance with the present invention, in which the optical fiber for pulling, the adapter and the branch optical core tube are fixed together using an adhesive tape.

<Explanation of symbols for the main parts of the drawings>

10 ... retractable optical cable 11,12 ... branched optical core

100 ... Adapter 110,141 ... Entrance

120,142 Exit 130 ... Through Q1 optical core

140 ... Information hole 150 ... 2nd quarter optical core through hole

200 ... Branch optical core tube 300 ... Heat shrinkable protective tube

400 ... adhesive tape

Claims (5)

An adapter having a single inlet into which an incoming optical cable is fitted and a plurality of outlets through which branch optical cores inside the incoming optical cable branched from the incoming optical cable exit; A branched optical core tube passing through the branched optical cores exiting from each outlet of the adapter and fitted into the outlet of the adapter while passing through the branched optical core; And A heat shrinkable protective tube fitted to the outside of the divergent optical core tube and sealing the branched portion while being heat-shrunk during the heating treatment; The adapter extending from the inlet of the adapter and having a diameter smaller than an outer diameter of the incoming optical cable and larger than an outer diameter of the branch optical core, and through the first branch optical core through hole; It has a guide hole formed to extend inclined to the exit, And the first branch optical core through hole and the guide hole are connected through a second branch optical core through hole whose diameter is smaller than the outer diameter of the incoming optical cable and larger than the outer diameter of the branch optical core. delete The method of claim 1, The outlet of the guide hole has a diameter smaller than the diameter of the branch optical core tube to be stepped with respect to each outlet of the adapter, And the inlet of the guide hole is formed to have a diameter smaller than that of the first branch optical core through-hole so as to be stepped with the first branch optical core through-hole. delete The method of claim 1, And the inlet optical cable and the branch optical core tube are fixed together with the adapter through an adhesive tape so as not to be separated from the adapter.

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