KR19980056968A - Mechanical Optical Splicer Seals - Google Patents

Abstract

The present invention relates to a seal for protecting a connector used when connecting an optical fiber to prevent foreign matter from penetrating.

When the mechanical optical connector seal 20 according to the present invention is divided into upper and lower cases 20a and 20b and overlapped with each other, the through grooves through which the receiving groove 21 and the optical fiber 1 are inserted are inserted. 23 was formed, and the hook surface 25 was formed on the edge surface of the case on one side, and the hook 27 was formed on the edge surface of the case on the other side so as to be inserted into the hook groove 25.

The splice closure body 20 according to the present invention provides an effect that can prevent the loss of optical connection because the foreign material does not penetrate the inside of the splicer.

Description

Mechanical Optical Splicer Seals

The present invention relates to a connector used when branching or connecting an optical fiber, and more particularly, to a seal for protecting foreign matter from penetrating the connector.

In general, optical communication is to exchange information by transmitting light through an optical fiber, and can transmit tens of thousands of times more information than electric communication by current coaxial cable. In addition, since the transmission state of the information is good because it is not influenced by the radio wave and the magnetic field from the outside, it is widely used in the communication field, and its use range is gradually expanding to other fields.

In recent years, the rapid recognition of informatization has required more optical cable lines. Recently developed optical cables are used to process a lot of information by producing ribbon-type multi-core optical cables in which a single optical fiber is integrated into a strip.

Such an optical cable is installed at a distance of several hundred kilometers or more, and thus requires connection and branching of the cable in the middle.

However, since optical fibers made of very small diameters (125 μm or 250 μm) are formed inside the optical cables, it is very difficult to connect the cores of the optical fibers to each other, and in the case of multi-core optical cables, a plurality of optical fibers are connected at once. It's even harder to do. In particular, if the optical fiber is installed in the home, its use will be even greater.

Various methods are used for the connection of optical fibers, and representative examples thereof include a fusion splicing method and a mechanical splicing method. The electronic fusion splicing method is a method of melting and connecting optical fibers and is mainly used for permanent connection.In order to achieve this, expensive precision fusion splicing apparatus must be used and a power source must be used. There is an advantage of high reliability of optical characteristics.

In addition, the mechanical optical cable connector has various advantages, such as convenience of work and no additional equipment, so that it can be easily connected even without a power source, and the reliability of the optical characteristics is almost the same as that of fusion splicing.

As described above, in connection and branching of optical fibers, a so-called connector or connector is used for mechanical connection.

An example of the conventional mechanical connector 10 is illustrated in FIG. 1, when the housings 10a and 10b divided up and down are overlapped with each other as shown in FIG. 1, the optical fiber 1 is disposed on the contact surface thereof. The groove 13 to be positioned is formed so that the cross section of the optical fiber is connected. Then, the upper and lower housings 10a and 10b were fixed around the circumference of the housing with respective bands 15 made of metal pieces so as not to move. In addition, a clamping fixing plate 17 is formed on the surface of the housing exposed between the respective bands 15 to precisely press and align the contact portions of the respective optical fibers 1 positioned on the grooves 13 therein. have.

However, as can be seen in the drawing due to the cutout portion (15a) formed on the surface of the band 15 has been accompanied with a problem that the phenomenon that the foreign matter is often introduced into the optical fiber. In particular, optical communications are critically vulnerable to moisture and must be protected from moisture.

Accordingly, the present invention has been devised to protect the mechanical optical connector from foreign matter.

It is an object of the present invention to provide a seal for protecting foreign matter from being inserted into a mechanical optical connector.

1 is a perspective view illustratively showing a mechanical optical connector.

2A and 2B are perspective views illustratively showing a protective seal enclosed to seal the mechanical connector shown in FIG. 1 in accordance with the present invention.

3A and 3B are exploded perspective views illustrating an exploded mechanical seal for protecting the optical connector according to the present invention.

Fig. 4A is a sectional view showing the main parts of a mechanical optical connector protective seal according to the present invention before assembly.

4B is a sectional view showing the principal parts of a mechanical post-connector protective enclosure according to the present invention, after assembly.

* Explanation of symbols for main parts of the drawings

1: optical fiber 10: splicer

10a: upper housing 10b: lower housing

13: home 15: band

20a: upper case 20b: lower case

21: storage groove 23: through groove

25: coupling groove 27: hook

When the upper and lower housings overlap each other, the mechanical optical connector seal according to the present invention forms grooves on the surfaces in contact with each other so that the end faces of the optical fibers are aligned, and is a band for fixing the outer wall of the upper and lower housings so as not to move. In the configured mechanical connector, when divided into the upper and lower cases and overlap each other, forming the receiving groove for receiving the mechanical connector is formed, and the engaging surface is formed on the edge surface of one case and inserted into the engaging groove on the edge surface of the other case It is to be implemented through the configuration consisting of hooks that are combined.

Hereinafter, the mechanical optical connector hermetic body according to the present invention will be described with reference to the accompanying drawings.

As shown in Figures 2a to 3b, the sealing body 20 according to the present invention is composed of upper and lower cases 20a, 20b. In each of the upper and lower cases 20a and 20b, an accommodating groove 21 is formed to accommodate the connector 10 as shown in FIG. 1, and through grooves through which the optical fiber 1 penetrates at both ends thereof. 23) is arranged.

Of the above-described upper and lower cases 20a and 20b, a plurality of locking grooves 25 formed at a predetermined depth around the edge of one side of the case, that is, around the accommodating groove 21 are arranged in plural, and the upper and lower cases are disposed on the other case. When 20a, 20b overlaps, the hook 27 inserted into the said locking groove 25 protrudes.

Referring to the operation according to the invention configured as described above are as follows.

As shown in FIGS. 3A and 3B, when the connector 10 having optical connection is positioned between the upper and lower cases 20a and 20b, and the respective cases are overlapped, the connector 10 is formed in the receiving groove 21. It is inserted and fixed to prevent movement. At this time, the case is moved in the axial direction of the case so that the hook 27 inserted into the locking groove 25 is caught in the locking groove 25 as shown in 4a so that the upper and lower cases 20a and 20b are not separated. .

Therefore, the hook 27 is caught in the locking groove 25 so that the upper and lower cases 20a and 20b are integrally coupled to surround the connector 10.

For reference, FIGS. 2b and 3b exemplarily show other shapes of the sealing body according to the present invention. The configuration and coupling relationship thereof are as described above, and the connector 10 may be the same as the type described above. As it is designed in a rectangular shape as well as the cross section is designed in a circular shape to seal the splice made in a circular shape may be used as shown in Figure 2b and 3b. And, in the present invention to form an accommodating groove for accommodating the connector by exemplarily having a rectangular shape to help understand the sealing body for protecting the connector, in addition to the internal structure of the accommodating groove may be changed according to the appearance of the connector Can be.

As described above, the mechanical connector sealing body according to the present invention surrounds the outside of the connector and prevents foreign matter from penetrating into the inside, thereby providing an effect of preventing the optical connection loss, and also primarily affecting external vibration. It also has the effect of mitigating impact and prevents foreign objects from getting damaged in the splice in general homes that are easily exposed to foreign materials.

Claims (1)

When divided into upper and lower cases 20a and 20b and overlapped with each other, an accommodating groove 21 in which the connector 10 is accommodated and a through hole 23 through which an optical fiber penetrates are formed, and an engaging groove ( 25) and the optical connector connector, characterized in that consisting of a hook (27) is inserted into the engaging groove (25) coupled to the edge surface of the case of the other side.