KR100319844B1 - Optical connector module - Google Patents

Abstract

Disclosed is an optical connector module capable of coupling at least one optical element having a light receiving source and an electrode for supplying power to the light emitting or receiving light, and at least one optical fiber transmitting incident light. It is.

The disclosed optical connector module includes: a first holder coupled to an optical element to guide an installation position of the optical element; A second holder coupled to one end of the optical fiber to guide the installation position of the optical fiber; An optical element installed in each of the first and second installation grooves, including a main body having a first installation groove in which the first holder is coupled and installed, and a second installation groove penetrating through the first installation groove and in which the second holder is coupled and installed. And end portions of the optical fiber can face each other.

Description

Optical connector module

The present invention relates to an optical connector module, and more particularly, to an optical connector module capable of coupling a light emitting device and an optical fiber.

In general, the optical connector module is employed in the optical transmission module, in particular, multi-channel optical transmission module having an array structure so as to transmit the light independently, and guides the light to proceed correctly by coupling the optical element and the optical fiber. The optical device is a light emitting device having a linear array structure and irradiating laser light, or a light receiving device having an array structure for receiving light transmitted through the optical fiber.

1 is a schematic exploded perspective view showing an example of a conventional optical connector module employed in a multi-channel optical transmission module.

As shown in the drawing, the conventional optical connector module includes a ferrule 10 for aligning one end positions of the optical fiber 3 such that the optical element 1 of the array structure and the plurality of optical fibers 3 face each other.

The ferrule 10 includes a substrate 11 having a plurality of grooves 11a formed in a V-shape so that each of the optical fibers 3 can be aligned, and the grooves 11a coupled to the substrate 11. It includes a cover member 13 for pressing the optical fibers (3) placed on each.

On the other hand, as shown in the optical device 1, when the light emitting device 2, such as a semiconductor laser is employed, in order to increase the light utilization efficiency, the light emitting device (2) between the light emitting device 2 and the optical fiber (3) It further comprises a microlens array 15 for focusing the light irradiated from 2) and incident on the optical fiber (3).

As described above, the conventional optical connector module has the following problems.

First, each of the plurality of optical fibers (3) must be aligned with the V-shaped groove (11a), so each of the optical fibers (3) must be handled separately. Therefore, the optical fiber is likely to be misaligned.

Second, since the substrate 11 must be machined to form a plurality of grooves 11a, the cost is high and the yield and productivity are lowered.

Third, since the microlens array 15 is provided between the light emitting element 2 and the optical fiber 3, an increase in the number of parts, complicated assembly labor, and high cost are caused.

Accordingly, an object of the present invention is to provide an optical connector module having an improved structure to facilitate alignment and to eliminate an auxiliary optical member such as a microlens array. .

1 is a schematic exploded perspective view showing an example of a conventional optical connector module employed in a multi-channel optical transmission module.

Figure 2 is a schematic diagram showing a multi-channel optical transmission module employing an optical connector module according to an embodiment of the present invention.

Figure 3 is an exploded perspective view showing an optical connector module according to an embodiment of the present invention.

4 is a cross-sectional view of FIG.

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

20 ... optical element 21 ... light emitting source 23 ... electrode

30 1st holder 31 ... electrode base 33 ... electrode fixing plate

34.Joining groove 40 ... Body 41 ... First mounting groove

43 Second installation groove 45 Guide rail 47 Stopper

50 ... optical fiber 60 ... second holder 63 ... guide projection

In order to achieve the above object, the present invention includes at least one optical element having a light emitting source and an electrode for applying power to the light emitting source to receive light or incident light; An optical connector module for coupling at least one optical fiber for transmitting incident light, the optical connector module comprising: a first holder coupled to the optical element to guide an installation position of the optical element; A second holder coupled to one end of the optical fiber to guide the installation position of the optical fiber; Each of the first and second installation grooves, including: a main body having a first installation groove in which the first holder is coupled and installed, and a second installation groove penetrating the first installation groove and in which the second holder is coupled and installed. The optical device and the ends of the optical fiber installed in the so as to be able to face each other.

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

2 is a schematic view showing an optical transmission module having a structure in which an optical device and an optical fiber are connected by an optical connector module, FIG. 3 is a perspective view of an optical connector module according to an embodiment of the present invention, and FIG. 4 is a cross-sectional view of FIG. .

2, the optical connector module according to the embodiment of the present invention is installed between the light emitting device 20 'and the optical fiber 50 and between the optical fiber 50 and the light receiving device 20 ", the light emitting device ( The light irradiated from 20 'is transmitted to the light receiving device 20 "through the optical fiber 50. The optical connector module includes a first holder 30 to which the optical elements 20 such as the light emitting element 20 'and / or the light receiving element 20 "are coupled, and a second holder 60 coupled to the end of the optical fiber. ) And a main body 40 on which the first and second holders 30 and 60 are installed.

The optical device 20 includes a light emitting source 21 for receiving light emission or incident light, and an electrode 23 for applying power to the light emitting source 21. The optical device 20 may have an array structure in which a plurality of light emitting devices are arranged adjacent to each other to enable multichannel signal transmission. The optical connector module according to the present embodiment is particularly useful for the optical transmission module having a multichannel structure as described above.

The first holder 30 guides the installation position of the optical device 20 so as to be connected to the optical transmission module having the multichannel structure so as to connect the optical device 20 and the optical fiber 50. The first holder 30 is installed to surround at least a portion of the optical device 20, an electrode base 31 fixedly supporting the electrode 23, and an electrode fixing plate 33 coupled to the main body 40. ). A coupling groove 34 to which the electrode base 31 is coupled is formed at one side of the electrode fixing plate 33 to guide the electrode base 31 to be coupled to the correct position of the electrode fixing plate 33. Here, the electrode base 31 is preferably manufactured by an insert mold or an insulating adhesive material with a part of the electrode 23 positioned therein so as to be integrated with the optical device 20. In addition, in order to prevent the flow of the electrode base 31 with respect to the electrode fixing plate 33, the electrode base 31 is preferably fixed to the coupling groove 34 by an electrically insulating adhesive.

The second holder 60 is coupled to surround a portion of the optical fiber 50 to guide the installation position of the optical fiber 50. Here, it is preferable that the second holder 60 is made of an insert mold or an insulating adhesive material and is integrated with the optical fiber 50 while one end of the optical fiber 50 is positioned therein.

The main body 40 has a first installation groove 41 to which the first holder 30 is coupled, and a second penetrating through the first installation groove 41 and to which the second holder 60 is coupled. It has an installation groove 43. The first installation grooves 41 and the second so that the ends of the optical device 20 installed in the first holder 30 and the optical fiber 50 installed in the second holder 60 face each other at a predetermined interval. The installation groove 43 is formed through. Here, a stopper 47 having a predetermined width is provided between the first installation groove 41 and the second installation groove 43 so that the distance between the optical device 20 and the optical fiber 50 is kept constant. It is preferable.

In addition, the guide means for guiding coupling to each of the second installation groove 43 and the second holder 60 to facilitate alignment of the optical axis of the optical fiber 50 with respect to the second installation groove 43 is formed. desirable. As the guide means, as shown in FIG. 3, the guide protrusion 63 formed in the coupling longitudinal direction on the bottom surface of the second holder 60 and the second installation groove 45 to correspond to the guide protrusion 63. The guide rail 45 may be formed. Therefore, the second holder 60 is prevented from flowing due to manufacturing tolerances between the second installation groove 43 and the second holder 60 so that the optical device 20 and the optical fiber 50 are correctly formed. Can be aligned.

As described above, in the optical connector module according to the present invention, the first holder and the second holder are installed on the optical element and the optical fiber, respectively, by insert molding or insulating adhesive, and each of the first and second mounting grooves of the main body is installed. By coupling the optical element and the optical fiber by coupling to each, it is possible to fundamentally eliminate misalignment between the optical fibers having an array structure.

In addition, the manufacturing cost can be reduced by manufacturing the first and second holders and the main body by using an insert mold or an insulating adhesive material, and a guide means is provided to guide the coupling position of the optical fiber with respect to the main body. Optical axis alignment is easy.

Claims (2)

It is for coupling at least one optical element having a light emitting source and an electrode for supplying power to the light emitting source so as to receive light emission or incident light, and at least one optical fiber for transmitting incident light, A first holder coupled to the optical element to guide the installation position of the optical element; A second holder coupled to one end of the optical fiber to guide the installation position of the optical fiber; Each of the first and second installation grooves, including: a main body having a first installation groove in which the first holder is coupled and installed, and a second installation groove penetrating the first installation groove and in which the second holder is coupled and installed. In the optical contactor module so that the ends of the optical element and the optical fiber installed in each other, The first holder may include an electrode base installed to surround at least a portion of the optical device to fix and support the electrode; And an electrode fixing plate having a coupling groove formed at one side such that the electrode base is coupled, and coupled to the first installation groove. The method of claim 1, wherein the guide means for guiding the coupling in each of the second installation groove and the second holder is formed to be able to prevent the flow of the second holder with respect to the second installation groove. Optical connector module.