KR101480833B1 - Optical connector and method for manufacturing the connector - Google Patents

Abstract

An optical connector for coupling optical cables is disclosed. The optical connector comprises: a body which includes a through hole for providing an optical path and an inner control space which is connected to the through hole; a lens holder which is installed in the control space enabling a position adjustment thereof, wherein a collimating lens and a stub ferrule are coupled with both ends of the lens holder; and a fixing unit which fixes the lens holder, whose position is adjusted in the control space, inside the control space.

Description

Technical Field [0001] The present invention relates to an optical connector and a manufacturing method thereof,

The present invention relates to an optical connector and a method of manufacturing the same, and more particularly, to an optical connector used in an optical communication line and a method of manufacturing the same.

The optical connector is an element for connecting the optical fiber and the optical fiber on the optical communication line, and it is very important to precisely align the optical fibers with each other. If the optical fiber is not aligned within an appropriate range, the optical communication itself is impossible, and even if the optical fibers are arranged in a state in which mutual optical communication is possible, the optical loss becomes large unless the accuracy is high.

In the case of a single-mode optical fiber other than a multi-mode optical fiber, a very high precision alignment is required between the optical fibers because the diameter of the light passing cores is very small, ranging from a few microns to tens of microns. For this reason, when the optical fiber connection is required, the connection operation is performed in a room with high cleanliness. However, inevitably, when an optical fiber is connected in an outdoor environment, the connection portion is contaminated by dust or foreign matter, resulting in light loss at the connection portion. In order to suppress such contamination and thus the occurrence of optical loss, a connector structure is used in which the beam is expanded while using a beam expanding collimating lens in the middle without directly connecting the optical fibers.

In such a structure, alignment between the lens and the optical fiber is very important, and therefore, a structure capable of more stably and precisely aligning or coupling the lens and the optical fiber is required.

The present invention provides an optical connector capable of effectively coupling an optical fiber and a method of manufacturing the same.

The present invention provides an optical connector that can accurately combine optical fibers to minimize optical loss and a method of manufacturing the same.

An optical connector according to the present invention comprises:

A body having a through hole providing an optical path and an internal control space leading to the through hole;

A lens holder having a collimating lens and a stub ferrule coupled to both ends of the lens holder so as to be adjustable in the control space;

A fixing portion for fixing a lens holder whose posture is adjusted within the control space within the control space; And a contact support provided between the through hole and the control space to provide a rotation point or a hinge point of the lens holder in the control space with one end of the lens holder being in contact therewith.

According to another embodiment of the present invention, a terminal of an optical cable is inserted into the control space in which the lens holder is located, and a terminal of the optical cable is coupled with the stub ferrule by a sleeve in the control space have.

According to a specific embodiment of the present invention, the terminal of the optical cable includes an optical fiber ferrule, and the sleeve can be coupled to the optical fiber ferrule and the stub ferrule.

According to another specific embodiment of the present invention, the fixing portion may be provided by an adhesive or welding.

A method of manufacturing an optical connector according to the present invention comprises:

Aligning the posture of the optical component holder with the optical component holder in contact with the contact support in the control space;

And permanently fixing the optical component holder whose posture is aligned in the control space to the body by the fixing part.

According to the present invention, the optical alignment between the optical connectors can be controlled very precisely. The optical alignment between the optical connectors is possible by the posture control of the lens holder provided inside the optical connector and its fixing structure, which reduces the light loss occurring in the connection structure between the optical cables. Further, the coupling and disconnection of the optical cable to the optical connector can be easily performed outdoors or outdoors.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a partial cutaway perspective view of an optical cable. FIG.
Fig. 2 shows an example of a multi-channel optical connector for contacting a plurality of optical cables.
FIG. 3A is a schematic cross-sectional view showing a state in which an optical connector according to the present invention is coupled with a master connector. FIG.
Figure 3b illustrates a method of aligning the posture of the lens holder, which is an internal optical component, in an optical connector according to the present invention.
FIG. 4 illustrates the relationship between a lens holder installed in a body interior control space and a control space for accommodating the lens holder in the optical connector according to the present invention.
5 is a partial cross-sectional view showing an optical cable connected to an optical connector according to the present invention.
Fig. 6 schematically shows the arrangement structure of the main optical components located on the optical path in the optical connector according to the invention.
7 is a plan view showing the arrangement and coupling state of the main optical components located on the optical path in the optical connector according to the invention.

Hereinafter, various embodiments of the optical connector according to the present invention will be described with reference to the accompanying drawings.

An optical cable includes an optical fiber having a core and a clad around the core, as is well known. Such an optical cable 20 includes a terminal 21 for coupling with another optical cable 20 or for connection with another element or system, as shown in Fig. 1, so as to be applicable to an optical communication apparatus. The terminal 21 includes an optical fiber ferrule 21a provided at the distal end of the optical fiber 22 and passing through the tip of the optical fiber 22 and a holder 21b for fixing the optical fiber ferrule 21a do. 1, reference numeral 21a 'denotes a cross section of the optical fiber 22 or a cross section of the core.

2 shows an embodiment of an optical connector 101 according to the present invention. The optical connector shown in Fig. 2 is connectable to a plurality of optical cables 20 for multi-channel use. The body 10 of the optical connector can be made of a metal such as stainless steel and has a plurality of through holes 10a through which light passes and an internal control space 10c (FIG. 3) spatially connected to each of the through holes 10a Respectively. In the control space 10c, a stub ferrule, a ball lens, and a lens holder for supporting the stub ferrule, which will be described later, corresponding to the terminal 21 of the optical cable 20 are provided. The optical cables 20 are fixed to the body 10 by an optical cable fixing mount 18 while being coupled to the stub ferrule. A mount 18 for fixing the optical cable to the body 10 is symbolically represented in Fig. This is because the technical scope of the present invention is not limited and can have various types of structures.

In Fig. 2, reference numeral "11" denotes a guide pin for guiding a connection with another mating connector. The optical connector 101 according to the present invention can be designed not only for a multi-channel but also for a single channel, and the technical scope of the optical connector according to the present invention is not limited to the number of channels.

Figure 3 shows a partial cross-sectional view of an embodiment of an optical connector according to the invention. 3, the through hole 10a formed in the upper surface of the body 10 of the optical connector accommodates a later-described lens holder 16, and a control space 10c for controlling the posture of the lens holder 16 ). The through hole 10a corresponds to the opening of the control space 10c, and a contact support portion 10b is provided between the through hole 10a and the control space 10c. The contact support portion 10b may be provided by a step between the through hole 10a having a different diameter and the control space 10. [ The tip of the lens holder 16 is entirely or partly contacted with the contact support portion 10b. At this time, the lens holder 16 may be fixed in the control space 10c by an adhesive such as an epoxy bond, laser welding or the like.

The lens holder 16 is a tubular body through which light can pass, and a ball lens 14 is mounted on one end or an upper portion thereof, and a stub ferrule 13 is fixed to the other end or the lower end thereof. The lens holder 16, the ball lens 15 mounted thereon, and the stub ferrule 13 are assembled together.

3A, the fixing of the lens holder 16 to the control space 10c of the connector body 10 is performed by bonding or laser welding the inner wall of the control space 10c And the fixing portion 17 is exemplified. In the present invention, the technical scope of the lens holder 16 is not limited by the specific fixing method or structure.

In fixing the lens holder 16 to the connector body 10, the lens holder 16 is inserted into the control space of the connector body 10 and then aligned in a two-dimensional or three-dimensional direction in the X, Should be preceded. At this time, it is possible to prepare the master connector 100 as a reference device for adjustment and to adjust the connector 101 to be adjusted with respect to the master connector 100, which is one preferable adjusting method. 3B, in the state in which the adjustment subject connector 101 is coupled with the master connector 100, in the control space 10c of the body 10, the lens holder 16 is moved in the X direction (Xt, Yt) centering on the X, Y axes and the X, Y axes. At this time, any part of the distal end portion 16b of the lens holder 16 have. That is, when the posture of the lens holder 16 is finely adjusted, the distal end portion 16b of the lens holder 16 and the contact supporting portion 10b corresponding thereto are partially in contact with each other, (Or a portion 10d) of the lens holder 16 to the hinge point (or portion) 10d. The portion providing the rotation point or the hinge point 10d may be provided independently or separately in the control space as well as the step portion provided by the structure as described above so that the distal end portion 16b of the lens holder 16 is in contact with It can be provided by any contact structure that can be supported.

The hinge point 10d, which can be provided by the nose contact support 10b provided by the step or separate structure or the like, is changed according to the alignment state of the lens holder 16, and the hinge point 10d, (10d) is permanently retained after forming the fixing portion (17). According to this structure, it is possible to precisely adjust the posture of the stub ferrule with respect to the ball lens, in particular, to precisely adjust the posture of the ball lens and the stub ferrule with respect to the connector body 10. [ Such self-adjustment includes a precise optical axis adjustment or matching process between the optical connector body and the body, thereby precisely controlling the optical coupling between the optical connectors.

Referring to Fig. 4, the optical fiber 13a having the tip end of the ball lens 14 is located at the focal point of the ball lens 14 in the body 13b of the stub ferrule 13. [ The lens holder 16 is inserted from the control space 10c under the body of the optical connector 10 at one end (upper end in the drawing) of the optical connector 10 with the ball lens 14 at the head, Is brought into contact with the side surface of the contact support portion 10b at the uppermost end of the control space 10c. The lens holder 16 includes a first region I in which a ball lens 14 is coupled and a stub ferrule 13 that is optically connected to the ball lens 14, 2 portion (II).

The lens holder 16 may be coupled to the terminal 21 provided at the distal end of the optical cable 20 in a state of being coupled to the body of the connector 10 as shown in FIG. The optical cable 20 is fixed to the body 10 by a mount 18 in a state where the optical cable 20 is coupled to the stub ferrule 13 exposed from the body 10 by the sleeve 15.

The other end (lower end in the drawing) of the stub ferrule 13 fixed to the lens holder 16 is optically aligned with the optical fiber ferrule 21a of the terminal 21 provided at the distal end of the optical cable 20 The stub ferrule 13 and the optical fiber ferrule 21a can be fixed by the sleeve 13 for this purpose. The sleeve 13 is an exemplary component for coupling two ferrules 13 and 21a together, and a ferrule connection structure of a specific structure or manner, such as the sleeve 13, does not limit the technical scope of the present invention Do not. However, the sleeve 13 is a preferable part for coupling the two ferrules 13 and 21a to each other.

Figs. 6 and 7 show the relative positions of the optical components in the optical connector according to the present invention and the coupling relationship therebetween, that is, the overall connection structure between the ball lenses 14 and the optical cables 20. Fig.

6, the ball lens 14 is opposed to the lens holder 16. In the state where the stub pulley 13 is inserted into the lens holder 16, the tip end of the ball lens 14 faces the ball lens 14 . The rear end of the stub ferrule 13 is coaxially positioned with the optical fiber ferrule 21a, and these are connected by a connecting member (component). The connecting member is, for example, a sleeve 13, and the stub ferrule 13 and the optical fiber ferrule 21a are inserted from both ends of the sleeve 13. It is preferable that the stub ferrule 13 and the optical fiber ferrule 21a have the same diameter so that the sleeve 13 can be obtained from a tubular body having a single diameter. The optical cable 20 has an optical fiber 22 and a terminal 21 as described above. The terminal 21 includes an optical fiber ferrule 21a connected to the optical fiber 22 and a holder 21b interconnecting the optical fiber ferrule 21a and the optical fiber ferrule 21a.

The sleeve 15 may be fixed or fixed to the side of the stub barrier 13 and may be fixed to the side of the terminal 21 according to another embodiment of the present invention. Moreover, the sleeve 15 can be structured such that it can be inserted and separated by an appropriate pressure without being fixed to the stub ferrule 13 or the terminal 21. [

According to the above structure, since the terminal 21 and the stub ferrule 13 can be easily coupled by the sleeve 15, and at this time, they have the same diameter, and the clearance that may exist therebetween is extremely small, Very precise alignment is possible. According to the present invention, it is possible to easily and precisely combine cables when the connector is replaced, the cable is replaced, or the cable is detached after reassembly for any reason. Since the ball lens and the corresponding stub ferrule are precisely adjusted by the characteristic structure of the present invention at this time, the coupling and separation can be performed by connecting the terminal to the stub ferrule by the sleeve It is very easy to achieve an optical connection that is precise and has little optical loss. In particular, since the stub ferrule and the terminal are coupled by the sleeve 15, the offset between the two elements does not occur even after the separation and recombination. The stub ferrule 13 and the sleeve 15 may be made of metal or nonmetal, and may be made of ceramic, for example.

As a result, according to the present invention, it is possible to precisely adjust the posture of the ball lens and the stub ferrule with respect to the connector body 10, and particularly, since the optical axis adjustment between the optical connector body and the body is possible, The optical loss in the communication line can be minimized.

The conventional optical connector has a simple structure in which the ball lens is fixed to the connector itself and the terminal of the optical cable is inserted and fixed in the connector. According to this structure, when the terminal is inserted into the optical connector at the work site, the inside of the connector provided with the ball lens may be contaminated. In addition, since the optical fiber ferrule of the optical cable is directly aligned with respect to the ball lens in the optical connector, misalignment may occur due to dispersion of characteristics of the optical fiber ferrule of the optical cable, (Misalignment) of the optical fiber ferrule with respect to the ball lens due to the movement of the ferrule may occur. Even if the terminal is initially properly aligned with the ball lens, this misalignment can also occur when the terminal is reinserted.

However, according to the present invention, a stub ferrule is provided between a ball lens and an optical cable in a body of an optical connector, and the ball lens and the stub ferrule are precisely aligned and then permanently fixed. In particular, the stub ferrules, which are precisely aligned with the ball lens and are maintained in this state permanently, are connected to a simple coupling part having a very small coupling or misalignment with the optical fiber ferrule provided at the terminal of the optical cable, All problems can be solved. That is, according to the present invention, it is possible to prevent dust contamination on a light path through which light passes, such as inside of an optical connector provided with a ball lens or a ball lens. On the other hand, as described above, since the optical fiber ferrules of the optical cable can be mutually coupled by using the stub ferrules aligned with respect to the ball lens by using a separate coupling part, for example, a tube-shaped sleeve or the like, And even if they are plugged in again at the work site, there is no misalignment between them, which would be a negligible size deviation of the coupling member such as a sleeve.

Although the optical connector according to the present invention has been described with reference to the embodiments shown in the drawings for the sake of understanding, the optical connector according to the present invention is merely an illustrative example, and various modifications and equivalent implementations You will understand that an example is possible. Accordingly, the true scope of the present invention should be determined by the appended claims.

10: Optical connector body
10a: Through hole
10b: step (of through hole)
10c: control space in the body
11: Guide pin
14: Collimating lens (ball lens)
15: Sleeve
20: Optical cable
21: Terminal
22: optical fiber

Claims (9)

A body having a through hole providing an optical path and an internal control space leading to the through hole; A lens holder having a collimating lens and a stub ferrule coupled to both ends of the lens holder so as to be adjustable in the control space; A fixing portion for fixing a lens holder whose posture is adjusted within the control space within the control space; And a contact support portion in which one end of the lens holder is in contact with the control space, the method comprising:
Aligning the posture of the lens holder with the lens holder in contact with the contact support in the control space; And
And permanently fixing the lens holder, whose posture is aligned in the control space, to the body by the fixing portion,
Wherein the posture of the lens holder is aligned using a hinge point at a contact portion between the distal end portion of the lens holder and the contact support portion. The method according to claim 1,
Wherein the terminals of the optical fiber and the stub ferrule are interconnected by a sleeve. 3. The method of claim 2,
Wherein the terminal of the optical cable comprises an optical fiber ferrule and the sleeve couples the optical fiber ferrule and the stub ferrule to each other. The method of claim 3,
Wherein the optical fiber ferrule and the stub ferrule have the same outer diameter and inner diameter. 5. The method according to any one of claims 1 to 4,
Wherein the fixing portion is provided by any one of an adhesive, a welding, and a mechanical fixing device. delete delete delete The method according to claim 1,
Wherein the stub ferrule and the optical fiber ferrule of the optical cable are coupled by a sleeve outside the body.

Images