KR101394250B1 - Machine type connecter for optical connection - Google Patents

Abstract

The present invention relates to a mechanical optical connector, and more particularly, to a mechanical optical connector in which a tapered portion is formed in a tensile holder screwed to a base, and a lid is closely attached to a base through a tapered portion to compress the optical fiber.

Description

[0001] MACHINE TYPE CONNECTER FOR OPTICAL CONNECTION [0002]

The present invention relates to a mechanical optical connector, and more particularly, to a mechanical optical connector in which a tapered portion is formed in a tensile holder screwed to a base, and a lid is closely attached to a base through a tapered portion to compress the optical fiber.

Korean Patent Application Publication No. 10-2009-0094744 entitled " a mechanical connector for optical fiber connection "includes an optical fiber connection base 11 having an optical fiber connection groove 11a through which optical fibers of two optical cables inserted at both ends are connected, A base cover member 12 which is fastened to the optical fiber connection groove 11 and presses the optical fiber to be connected in the optical fiber connection groove 11a and the optical fiber connection base 11 and the base cover member 12, And a fixing clamp 13 and 13 'for pressing the optical fiber in the optical fiber connection groove 11a so as to be pressed against the base cover member 12 while being slid to the central portion from the end side of the optical fiber connection base 11, ).

The mechanical connector 10 for connecting an optical fiber connects the optical fibers at both sides of the optical fiber connection base 11 to correspond to two optical fibers for mutual connection in the optical fiber connection groove 11a, The connection of the optical fiber is completed by pushing the fixing clamps 13 and 13 'fastened around the outer surface of the base cover member 12 to the center of the base cover member 12 and pressing them.

However, in the conventional mechanical connector, there is a problem that a configuration for pulling the optical fiber is not provided. To solve such a problem, a splice member added with a member for pulling the optical fiber is proposed, but the structure is complicated.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a mechanical optical connector for compressing an optical fiber with a simple structure.

According to an aspect of the present invention, there is provided a mechanical optical connector including a base on which an optical fiber connection groove is formed, a cover covering the optical fiber connection groove, a connection holder for coupling the cover to the base, A thread is formed on the outer circumference of the base and on the inner wall of the tensile holder, and a tapered portion is formed in the tensile holder so that the diameter of the hole increases toward the end.

The lid and the base may be disposed in the tapered portion, and a compression protrusion may be formed on the lid and the base to compress the optical fiber so as to be disposed between the optical fiber connection groove and the thread.

Wherein the tapered portion includes a first inclined portion and a second inclined portion inclined with respect to the first inclined portion and disposed at an end of the tension holder, And a plurality of grooves are formed along the longitudinal direction on the outer circumferential surface of the tensile holder, and a plurality of grooves are formed in the cover, Wherein the tongue portion is provided with the tensile protrusion and the base, and both sides of the base are formed with guide grooves communicating with the optical fiber connection groove, and the cover and the screw are disposed between the guide groove and the screw thread, A plurality of compression protrusions for compressing the optical fiber are formed on the base, and the plurality of compression protrusions are disposed along the longitudinal direction , The pressing projection has an inclined surface facing the optical fiber connection groove may be formed having a thickness larger toward the optical fiber connection groove thin.

According to the mechanical optical connector of the present invention as described above, the following effects can be obtained.

A tapered portion is formed in a tensile holder screwed to the base, and the lid is tightly attached to the base through a tapered portion to compress the optical fiber, thereby effectively pulling the optical fiber.

The lid and the base are disposed inside the tapered portion to cover the optical fiber connection groove through the lid and to pull the optical fiber.

The lid and the base are provided with compression protrusions for compressing the optical fiber so as to be disposed between the optical fiber connection groove and the thread, so that the optical fiber can be compressed more effectively.

FIG. 1 is a perspective view of a conventional mechanical optical connector. FIG.
FIG. 2 is a perspective view of a mechanical optical connector according to a preferred embodiment of the present invention. FIG.
Figure 3 is a cross-sectional view of the mechanical optical connector of Figure 2 (longitudinal direction)
FIG. 4 is a perspective view of the mechanical optical connector of FIG. 2; FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

For reference, the same components as those of the conventional art will be described with reference to the above-described prior art, and a detailed description thereof will be omitted.

2, the mechanical optical connector according to the present embodiment includes a base 100 on which an optical fiber connection groove 110 is formed, a lid 200 covering the optical fiber connection groove 110, And a tensile holder 400 having a hole for receiving the end of the base 100. The base 100 and the tension holder 400 The tapered portion 430 is formed in the tensile holder 400 such that the diameter of the hole increases toward the end.

In the base 100, an optical fiber connection groove 110 is formed along the longitudinal direction at a central portion, and a tensile portion 160 is formed at both ends.

The base 100 has a rectangular cross-sectional shape, and the tensile portion 160 has a circular cross-sectional shape.

The optical fiber connection groove 110 is formed on the upper surface of the base 100 so that the upper portion thereof is opened.

A storage groove 120 for storing a matching gel (not shown) is formed at the center of the base 100, which is a portion where two optical fibers are connected to communicate with the optical fiber connection groove 100.

A mounting groove 130 in which the protrusion 210 of the lid 200 is mounted is formed on the base 100 so as to communicate with the optical fiber connection groove 110 along the longitudinal direction.

A guide groove 150 is formed on both sides of the base 100 so as to communicate with the optical fiber connection groove 110 and the seating groove 130.

The guide groove 150 is formed to have a triangular cross-sectional shape and to be narrowed toward the center of the base 100.

The guide groove is formed so as to correspond to the guide groove 150 on the bottom surface of the protrusion 210 of the cover 200 described below.

Further, the base 100 is formed with spacing protrusions 140 for separating the lid 200 from the base 100 so as to be disposed on both sides of the inside of the seating groove 130.

More specifically, the spacing protrusions 140 are disposed outside the guide grooves 150, respectively.

Both sides of the base 100 are formed with an optical fiber through hole 101 penetrating through the tensile portion 160 and communicating with the guide groove 150.

The pulling portion 160 is formed to have a smaller cross-sectional area than the center portion of the base 100, and the pulling portion 160 is formed to be stepped.

An insertion hole 163 through which the tension projection 260 of the lid 200 described below is inserted is formed in the upper portion of the tension portion 160.

The insertion hole 163 is formed so as to communicate with the optical fiber drawing hole 101.

The lid 200 is disposed on the base 100 to cover the optical fiber connection groove 100.

The lid 200 is formed in a bar shape, and a protrusion 210 is formed in the lower portion along the length direction.

A stopper 230 is formed on the upper surface of the lid 200 and an upper protrusion 240 is formed on both sides of the stopper 230. An end of the upper protrusion 240 adjacent to the stopper 230 is formed with an inclined surface 220 at the opposite end.

A stopper is also formed on the bottom of the base 100.

On both sides of the cover 200, a tensile protrusion 260 inserted into the insertion hole 163 is formed.

The upper and lower heights of the tensile protrusions 260 are formed to be inclined so as to become smaller toward both ends. Thus, the tensile protrusion 260 can be formed, the tensile protrusion 260 can be elastically deformed well, and the durability of the tensile protrusion 260 can be improved.

The tensile protrusions 260 are formed so as to be narrower in width than the central portion of the lid 200 and are stepped. As a result, elastic deformation of the tensile protrusion 260 can be facilitated.

A protrusion 250 protrudes from an end of the tensile protrusion 260 and an inclined surface is formed at an end of the protrusion 250.

The connection holder 300 couples the lid 200 to the base 100.

The connection holder 300 is formed with a through hole 310 through which the lid 200 and the base 100 pass.

A plurality of friction grooves 320 are vertically formed on one side of the outer circumferential surface of the connection holder 300.

When the connection holder 300 is fitted into the lid 200 and the base 100 due to the friction grooves 320, the connection holder 300 is easily slidably fitted.

The tension holder 400 is formed with a hole 410 through which the tension portion 160, which is an end of the base 100, is inserted along the longitudinal direction.

3, threads 161 and 440 are formed on the outer circumferential surface of the tension portion 160 of the base 100 and on the inner wall of the tension holder 400. As shown in FIG.

A tapered portion 430 is formed in the tensile holder 400 such that the diameter of the hole 410 increases toward the end (toward the center of the base 100).

The tapered portion 430 includes a first inclined portion 431 and a second inclined portion 432 inclined with respect to the first inclined portion 431 and disposed at an end of the tension holder 400.

The angle a between the first inclined portion 431 and the outer surface of the tension holder 400 is smaller than the angle b between the second inclined portion 432 and the outer surface of the tension holder 400.

As described above, the tapered portion 430 is formed and the protrusion 250 can be easily inserted into the tapered portion 430.

At the end of the tensile holder 400, a catching protrusion 450 for catching the tensile portion 160, which is an end of the base 100, is formed.

In addition, a plurality of grooves 420 are formed on the outer circumferential surface of the tensile holder 400 along the longitudinal direction. As a result, the friction coefficient of the outer circumferential surface of the tension holder 400 is increased, and the tension holder 400 can be easily rotated.

A pair of compression protrusions 162 and 270 for compressing an optical fiber are provided on a lower portion of the tensile protrusion 260 of the lid 200 and an inner wall of the tensile portion 160 of the base 100 so as to be disposed between the guide groove 150 and the screw thread 161, .

Several pressing protrusions 162 and 270 are formed and arranged along the longitudinal direction.

The pressing projections 162 and 270 are formed with inclined surfaces 163 facing the optical fiber connection groove 110 so that the pressing protrusions 162 and 270 become thinner toward the center.

Hereinafter, the operation of the present embodiment having the above-described configuration will be described.

The optical fiber is inserted into the optical fiber outflow hole 101 on both sides of the base 100 and guided into the guide groove 150 and then placed in the optical fiber connection groove 110.

The optical fibers sandwiched from both sides are connected at the center of the base 100, and the matching gel is inserted into the storage groove 120.

The protrusion 210 of the lid 200 is seated in the seating groove 130 and the tensile protrusion 260 is inserted into the insertion hole 163 to cover the optical fiber connection groove 110. The seated lid 200 is engaged with the base 100 in both the forward and backward directions and fixed in position.

The connection holder 300 is slid on both sides of the base 100 along the inclined surface 220 to be fitted into the upper protrusion 240. The connection holder 300 is inserted until it is caught by the stopper 230. The connection holder 300 can be easily fitted to the predetermined position due to the stopper 230. [ In addition, the lid 200 can be formed to have a thick upper and lower portion of the portion to be fitted in the connection holder 300, to easily fit the connection holder 300 through the thinner portion, 200 can be brought into close contact with the base 100 with the connection holder 300 effectively.

The tension holder 400 is threaded to the tensioning portion 160.

As the screw connection is made, the tensile protrusion 260 is fitted into the smaller diameter side of the tapered portion 430 of the tensile holder 400. The tensile protrusion 260 can be smoothly inserted due to the inclined surface of the protrusion 250 when the tensile protrusion 260 is inserted into the tapered portion 430. After the fitting is completed, the protrusion 250 is elastically deformed due to the protrusion 250 .

This fitting operation is completed when the tension unit 160 is caught in the latching jaw 450 and the tension holder 400 is no longer caught in the tension unit 160.

When the tension holder 400 is screwed to the tension unit 160, the distance between the tension unit 160 and the tension projection 260 is narrowed, and the tension unit 160 is disposed between the tension unit 160 and the tension projection 260 The optical fiber is compressed and becomes an optical fiber tensile force.

The pressing protrusions 162 and 270 are formed on the inner wall of the tension portion 160 and the lower portion of the tension projection 260 so that the pressing protrusions 162 and 270 compress the optical fiber as the gap between the pressing protrusions 162 and 270 is narrowed, Can be more effectively achieved.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims .

DESCRIPTION OF REFERENCE NUMERALS
100: base 110: optical fiber connection groove
120: Storage groove 200: Cover
300: connection holder 400: tensile holder

Claims (4)

A base on which an optical fiber connection groove is formed;
A cover covering the optical fiber connection groove;
A connection holder for coupling the cover to the base;
And a tensile holder having a hole in which the base is inserted,
A thread is formed on the outer surface of the base and the inner wall of the tension holder,
A tapered portion is formed in the tensile holder so that the diameter of the hole increases toward the end,
Wherein the lid is provided with a tensile protrusion disposed inside the tapered portion,
And the tensile protrusion and the base are disposed inside the tapered portion. The method according to claim 1,
And the cover and the base are disposed inside the tapered portion. 3. The method according to claim 1 or 2,
And a compression protrusion for compressing an optical fiber is formed on the cover and the base so as to be disposed between the optical fiber connection groove and the thread. The method according to claim 1,
Wherein the tapered portion includes a first inclined portion and a second inclined portion formed to be inclined with respect to the first inclined portion and disposed at an end of the tension holder,
Wherein the first inclined portion is smaller in angle with the outer surface of the tension holder than the second inclined portion,
Wherein the tension holder is provided with a stopping jaw for receiving the base,
A plurality of grooves are formed on the outer peripheral surface of the tension holder along the longitudinal direction,
Guide grooves are formed on both sides of the base to communicate with the optical fiber connection grooves,
A compression protrusion for compressing an optical fiber is formed on the cover and the base so as to be disposed between the guide groove and the thread,
The plurality of compression protrusions are disposed along the longitudinal direction,
Wherein the compression protrusion is formed with an inclined surface facing the optical fiber connection groove, the thickness of which becomes thinner toward the optical fiber connection groove.

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