KR101235380B1 - Optical connector for high power laser - Google Patents

Abstract

The present invention relates to an optical connector for a high power laser, and more particularly, for a high power laser having a structure that can be mechanically coupled and dissipated smoothly without using an adhesive that is damaged by heat generated in the process of transmitting a high power laser. It relates to an optical connector.
In the high-power laser optical connector according to the present invention, in the high-power laser optical connector in which the end of the optical fiber is coupled to combine the optical fiber transmitting the high-power laser with another optical fiber or to connect the optical fiber to any other optical component, An outer ferrule in which the inner ferrule insertion portion and the split holder fastening portion are stepped sequentially from the through hole through which the front end portion of the optical fiber is inserted, and an inner ferrule in which the through hole through which the optical fiber is inserted is formed and inserted into the inner ferrule insertion portion; A split holder in which a through hole into which an optical fiber is inserted is formed and a split portion cut into a plurality of parts in a longitudinal direction is formed, and the split portion is tightened while the split portion is inserted into the split holder fastening portion and one end of the outer ferrule Connecting member coupled to the outer circumference and connected to another optical fiber Or a connection member coupled to the connecting member provided in the other optical component, and the heat dissipation portion is fastened to the outer periphery of the other end of the outer ferrule and the heat radiation fin is formed on the outer surface.

Description

Optical connector for high power lasers {OPTICAL CONNECTOR FOR HIGH POWER LASER}

The present invention relates to an optical connector for a high power laser, and more particularly, for a high power laser having a structure that can be mechanically coupled and dissipated smoothly without using an adhesive that is damaged by heat generated in the process of transmitting a high power laser. It relates to an optical connector.

Recently, the application of laser is expanding to medical, imaging, spectroscopy and processing technology as well as communication field. As a result, the available power of the laser is increasing from several W to several hundred W, which is required to develop components suitable for high power.

Optical connector for high power laser is a component used for coupling optical fiber and optical fiber or optical fiber and optical component. It should not only have low loss of optical connector itself but also be able to withstand high power laser when transmitting laser in high power trend. It shall not be damaged by heat generated by high power.

In addition, the optical connector should have a simple coupling structure for connecting and separating the optical fiber and the optical connector.

Republic of Korea Patent Application Publication No. 10-2008-0081789 (On-site assembly type optical connector), Republic of Korea Patent Publication No. 10-2011-0021615 (POF optical connector using a large diameter zirconia capillary and its manufacturing method) and Republic of Korea Patent Publication 10-2009-0107278 (field-assembled clamp type optical connector) and the like disclose various optical connectors. However, the above-described general optical connector is an optical component used to transmit a low power communication optical signal, and is not suitable for transmitting a high power laser, but also has complex problems.

The present invention was conceived by recognizing the above point is an object of the present invention is a high power of the structure that can be mechanically coupled and heat dissipation can be made smoothly without using an adhesive that is damaged by heat generated in the process of transmitting a high power laser It is to provide an optical connector for a laser.

In order to achieve the above object, an optical connector for a high power laser according to the present invention is coupled to an end portion of an optical fiber to couple an optical fiber transmitting a high power laser to another optical fiber or to connect the optical fiber to some other optical component. In the high-power laser optical connector, an outer ferrule in which the inner ferrule insertion portion and the split holder fastening portion are stepped sequentially from the through hole through which the leading end of the optical fiber is inserted, and the through hole through which the optical fiber is inserted are formed, and the inner ferrule is inserted. A split portion formed with an inner ferrule inserted into the portion and a through hole into which the optical fiber is inserted, and a split portion cut into a plurality of parts in a longitudinal direction at one end thereof so that the split portion is inserted into the split holder fastening portion and tightened; A holder and an outer periphery of one end of the outer ferrule It characterized in that the heat entered into the outer circumference at the other end of the connecting member and the outer ferrule is coupled to the connecting member with the connecting member or other optical component connected to the other optical fiber is formed with a radiation fin on the outer surface portion having.

In addition, the high-power laser optical connector according to the present invention is characterized in that the step between the inner ferrule insertion portion and the split holder fastening portion is tapered so that the diameter becomes smaller while proceeding from the split holder fastening portion to the inner ferrule insertion portion. It is done.

In addition, the high power laser optical connector according to the present invention is characterized in that the split holder fastening portion is formed to gradually decrease in diameter while advancing from the entrance to the inner ferrule insertion portion side.

In addition, the optical connector for high power laser according to the present invention, the gap space for exposing the front end of the optical fiber passing through the through hole of the outer ferrule is formed on the opposite side of the inner ferrule insertion portion with respect to the through hole of the outer ferrule. It features.

By the above configuration, the high-power laser optical connector according to the present invention has an advantage that the heat dissipation can be smoothly coupled without using an adhesive that is damaged by heat generated in the process of transmitting the high power laser.

1 is an exploded perspective view showing an optical connector for a high power laser according to an embodiment of the present invention
Figure 2 is a side view showing an optical connector for a high power laser according to an embodiment of the present invention
3 is a cross-sectional view showing an optical connector for a high power laser according to an embodiment of the present invention.
Figure 4 is an exploded cross-sectional view showing an optical connector for a high power laser according to an embodiment of the present invention
Figure 5 is a cross-sectional view showing a state in which the optical fiber is coupled to the optical connector for high power laser according to an embodiment of the present invention

Hereinafter, an optical connector for a high power laser according to the present invention will be described in more detail with reference to the embodiment shown in the drawings.

1 is an exploded perspective view showing an optical connector for a high power laser according to an embodiment of the present invention, Figure 2 is a side view showing an optical connector for a high power laser according to an embodiment of the present invention, Figure 3 is a present invention 4 is a cross-sectional view illustrating an optical connector for a high power laser according to an embodiment of the present invention, FIG. 4 is an exploded cross-sectional view illustrating an optical connector for a high power laser according to an embodiment of the present invention, and FIG. 5 is an embodiment of the present invention. The optical fiber is coupled to the high power laser optical connector according to the cross-sectional view showing a state.

The optical connector for high power laser according to the present invention combines an optical fiber cable (C) for transmitting a high power laser with another optical fiber (not shown) or the optical fiber cable (C) with a predetermined other optical component (not shown). It is an optical component to which the distal end of the optical fiber cable C is coupled so as to be connected to it.

Referring to the drawings, the high-power laser optical connector according to an embodiment of the present invention is the outer ferrule 10, the connecting member 20, the C-ring 30, the inner ferrule 40, the washer 50, split The holder 60 and the heat dissipation member 70 are provided.

The outer ferrule 10 is an optical fiber cable (C) in which the coating (C2) has been removed therein is inserted into the inner ferrule 40 inserted into the optical fiber portion (C1), the optical fiber portion inserted into the inner ferrule 40 Split holder 60 for fastening the optical fiber portion (C1) is fastened so that (C1) does not fall, it is a configuration for coupling the connection member 20 and the heat dissipation member 70 to the outer circumference. Referring to the drawings, the outer ferrule 10 is formed with a through hole 18 through which the front end portion of the optical fiber C1 from which the coating C2 has been removed is inserted, and the inner ferrule is sequentially inserted from the through hole 18. The portion 15 and the split holder fastening portion 17 are formed stepped. In addition, the outer ferrule 10 has a front end of the optical fiber C1 that has passed through the through hole 18 of the outer ferrule on the opposite side of the inner ferrule insertion portion 15 with respect to the through hole 18 of the outer ferrule. The gap space 11 for this exposure is formed. The gap space 11 is to provide a space for heat dissipation generated from the optical fiber C1. On the inner surface of the split holder fastening portion 17, a female screw for fastening a male screw formed on the outer circumference of the split portion 62 of the split holder 60 is formed. On the other hand, the split holder fastening portion 17 is for tightening the split portion 62 while the split holder 17 is fastened, and the tightening operation is made smoothly as the split portion 62 is fastened The split holder fastening portion 17 is formed to gradually decrease in diameter while proceeding from the inlet to the inner ferrule inserting portion 15. On the other hand, the inner ferrule 40 is inserted into the split holder fastening portion 17 and is inserted into the inner ferrule inserting portion 15 through the split holder fastening portion 17, the split holder fastening portion 17 In step into the inner ferrule insert 15, the step is tapered so that the split holder fastening portion 17 is not caught by the step of the ferrule insert 15. That is, the step between the inner ferrule inserting portion 15 and the split holder fastening portion 17 is tapered in a shape of decreasing diameter while proceeding from the split holder fastening portion 17 to the inner ferrule inserting portion 15. 16 is formed. On the other hand, the outer periphery of the outer ferrule 10 is provided with a connecting member 20, the heat release member 70 is fastened. C-ring 30 is mounted in a ring groove 13 formed in an annular concave shape in the middle of the outer ferrule 10 so that the connecting member 20 is not separated from the outer ferrule 10 and the ring groove 13 At the position away from the one end direction from) the engaging jaw (12) is formed to protrude in an annular shape so as not to fall off. A fastening portion 14 inserted into the heat dissipation member 14 and fastened to a female screw formed on the heat dissipation member 14 is formed on an outer circumferential surface of the other end of the outer ferrule 10. The outer ferrule 10 is made of a metal material having excellent thermal conductivity so that heat generated from the optical fiber C1 is well conducted to the heat dissipation member 70.

The connecting member 20 is configured to be coupled to a connecting member (not shown in the drawing) of another optical connector in order to connect the optical connector according to the present invention to another optical connector (not shown). That is, the outer member 10 is connected to the outer periphery of one end of the outer ferrule 10 so that the outer member 10 is inserted into the connecting member 20 so as not to be separated therefrom. Combined. Referring to the drawings, the inner peripheral surface of the connecting member 20 from the outer ferrule 10 in a state in which the fastening portion 21 is formed with a female thread for the other connecting member is screwed and the outer ferrule 10 is inserted It is located between the engaging jaw 12 formed on the outer circumference of the outer ferrule 10 and the C-ring 30 mounted on the outer circumference of the outer ferrule 10 so as not to be separated. A locking jaw 22 for catching 30 is formed to protrude in an annular shape on the inner circumferential surface.

As described above, the C-ring 30 inserts the outer ferrule 10 into the connection member 20, and then the engaging jaw 22 of the connection member 20 is disposed so that the outer ferrule 10 does not fall out. It is configured to be mounted to the ring groove 13 of the outer ferrule 10 so as to catch.

The inner ferrule 40 is configured to be mounted inside the outer ferrule 10 with the distal end portion of the optical fiber C1 from which the coating C2 is removed is inserted into the central through hole 41. The outer ferrule 40 enters the split holder fastening portion 17, passes through the split holder fastening portion 17, is inserted into the inner ferrule inserting portion 15, and is pressed by the split holder 60 to the rear. It is fixed to the inside of the inner ferrule insert 15 so as not to fall out. The inner ferrule 40 is preferably made of a sapphire material excellent in heat properties and excellent thermal conductivity.

The washer 50 is inserted into the split holder fastening part 17 so as to push the inner ferrule 40 and the inner ferrule 40 inserted into the inner ferrule insertion part 15. It is a structure for preventing direct contact between the rear end of the inner ferrule 40 and the front end of the split portion 62 of the split holder 60 and buffering the pressing force interposed therebetween.

The split holder 60 is configured to hold the optical fiber C1 fastened to the outer ferrule 10 and inserted into the inner ferrule 40 and the outer ferrule 10. Referring to the drawings, the split holder 60 has a through hole 63 in which a portion in which the coating C2 of the optical fiber cable C is held is formed at the center thereof, and a plurality of split holders 60 are formed at one end (front end) in the longitudinal direction. The split part 62 cut into the cutting gap 62a is divided and the head 61 is formed at the other end (rear end). The split holder 60 is coated with the optical fiber cable C inserted into the through hole 63 while the split portion 62 is tightened while the split portion 62 is inserted into the split holder fastening portion 17. The portion held by (C2) is tightened so as not to fall out. In particular, as described above, the split holder fastening part 17 is narrowly formed as the split part 62 enters, so that the split part 62 is fastened well as the split part 62 is fastened.

The heat dissipation member 70 is coupled to the outer ferrule 10 is a cylindrical configuration for discharging the heat transferred through the outer ferrule 10 to the outside air. Referring to the drawings, the heat dissipation member 70 is formed in the female screw portion 71 for fastening by inserting the fastening portion 14 of the outer ferrule 10 to the inner peripheral surface of one end portion, the thermal contact area on the outer peripheral surface Heat dissipation fins 72 for increasing are formed. On the other hand, the heat dissipation member 70 is screwed into the screw 80 for tightening and holding the jacket portion (C3, C4) of the optical fiber cable (C) so that the optical fiber cable (C) does not fall out of the heat dissipation member (70). The fastening hole 73 is formed at the rear end.

The optical connector for the high power laser and drawings described above are only one embodiment for carrying out the present invention, and should not be construed as limiting the technical idea of the present invention. The scope of protection of the present invention is defined only by the matters set forth in the claims below, and the embodiments which have been improved and changed without departing from the gist of the present invention will be apparent to those skilled in the art. It will be said to belong to the protection scope of the present invention.

10 outer ferrules
11 gap space
12 jaws
13 ring groove
14 Fasteners
15 Inner Ferrule Insert
16 taper
17 Split holder fastening
20 Connecting member
30 C-rings
40 inner ferrule
50 washers
60 split holder
61 head
62 splits
62a incision
70 heat release member

Claims (4)

In the optical connector for a high power laser to which the end of the optical fiber is coupled to couple the optical fiber transmitting the high power laser to another optical fiber or to connect the optical fiber to some other optical component,
An outer ferrule in which an inner ferrule insertion portion and a split holder fastening portion are stepped sequentially from a through hole through which an end portion of the optical fiber is inserted;
An inner ferrule formed with a through hole through which an optical fiber is inserted and inserted into the inner ferrule insertion unit;
A split holder in which a through hole into which an optical fiber is inserted is formed and a split portion cut into a plurality of parts in a longitudinal direction is formed at one end thereof, and the split portion is tightened while the split portion is inserted into the split holder fastening portion;
A connection member coupled to an outer circumference of one end of the outer ferrule and coupled to a connecting member connected to another optical fiber or a connecting member provided in another optical component;
Is provided with a heat dissipation member fastened to the outer periphery of the other end of the outer ferrule and the heat dissipation fin is formed on the outer surface,
A gap space for exposing the tip of the optical fiber passing through the through hole of the outer ferrule is formed on the opposite side of the inner ferrule insertion portion relative to the through hole of the outer ferrule. The method of claim 1,
And the step between the inner ferrule insertion portion and the split holder fastening portion is tapered to have a smaller diameter while proceeding from the split holder fastening portion to the inner ferrule insertion portion. The method according to claim 1 or 2,
And the split holder fastening portion is formed to gradually decrease in diameter while advancing from the inlet to the inner ferrule insertion portion. delete

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