KR100307585B1 - Optical connector module - Google Patents

Abstract

PURPOSE: An optical connector module is provided to prevent a crosstalk between neighboring channels by improving a structure of an optical connector module. CONSTITUTION: A plurality of optical devices(21) are installed on a base(31) of the first holder(30). The first holder(30) includes the base(31) and a multitude of lead members(33). The optical devices(21) have a light emitting device and a light receiving device for outputting or receiving an optical signal and converting the received optical signal to an electric signal. The second holder(50) is used for supporting each end portion of a plurality of optical fibers and guiding an installation position of the optical devices(21). The first and the second holders(30,50) are installed on a main body(40). The second holder(50) is combined with the main body(40) by using a combination portion. A separating groove(61) is formed between the optical fibers of the first holder(30). A barrier rib(63) is formed in the second installation portion(43).

Description

Optical connector module

The present invention relates to an optical connector module, and more particularly, to an optical connector module capable of coupling an optical element and an optical fiber.

In general, the optical connector module is employed in the optical transmission module, in particular, a multi-channel optical transmission module having an array structure so as to transmit light independently from each other to couple 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 separated perspective view showing an example of a conventional optical connector module employed in a multi-channel optical transmission module.

Referring to the drawings, the conventional optical connector module includes a ferrule 10 for aligning one end positions of the optical fiber 3 so that the optical element 1 of the array structure and the plurality of optical fibers 3 face each other.

The ferrule 10 is 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 each of the grooves 11a in combination with the substrate 11. It includes a cover member 13 for pressing the optical fibers (3) placed in the.

In the conventional optical connector module configured as described above, when the optical element 1 is a light receiving element, the optical signal emitted from the optical fiber 3 due to diffraction at the exit of the optical fiber 3, i. In addition to the device, a portion of the light receiving device may be detected in an adjacent position, and cross talk may occur between adjacent channels.

In addition, in the case where the optical device 1 is a light emitting device, since the optical signal emitted from the light emitting device is incident and transmitted not only to the corresponding correct optical fiber 3 but also to the optical fibers 3 which are adjacent to each other, the cross between the optical signal transmission channels Cross talk may occur.

The present invention has been made in view of the above, and an object thereof is to provide an optical connector module having a structure capable of preventing cross talk between adjacent channels.

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

Figure 2 is an exploded perspective view showing an optical connector module according to an embodiment of the present invention,

3 is a cross-sectional view of FIG.

* Explanation of symbols for main parts of the drawings

21 Optical element 23 Optical fiber

30 1st holder 31 ... base

33.Lead member 40.Body

41,43 ... 1st and 2nd mounting part 50 ... 2nd holder

Separation groove 63 Bulkhead

71 ... clamping member 73 ... engagement hole

According to an aspect of the present invention, there is provided an optical connector module for coupling a plurality of optical elements for emitting an optical signal and / or receiving an optical signal and converting the optical signal into an electrical signal, and a plurality of optical fibers for transmitting incident light. A first holder in which an optical element is installed; A second holder supporting one end of the optical fiber; A main body having first and second mounting portions respectively provided with the first and second holders so that the ends of the optical element and the optical fiber face each other with a predetermined distance therebetween; A separation groove formed between the optical fiber of the first holder, and a partition wall formed in the second installation portion to fit into the separation groove when the second holder and the main body are coupled to each other, and to block an optical signal from being transmitted to an adjacent channel. Means for limiting crosstalk between adjacent channels; And coupling means for coupling the second holder with the main body.

Here, the coupling means, the clamping member is installed in the second holder and capable of elastic deformation; And a coupling hole formed in the main body and configured to elastically slide and engage the clamping member when the second holder is installed in the second installation unit.

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

2 is an exploded perspective view showing an optical connector module according to an embodiment of the present invention, Figure 3 is a cross-sectional view of FIG. Here, the optical connector module according to an embodiment of the present invention is employed in the optical transmission module having a multi-channel structure is installed between a plurality of optical fibers and a plurality of light receiving elements and between a plurality of light emitting elements and a plurality of optical fibers to provide an optical element and an optical fiber. Coupling

Referring to the drawings, the optical connector module according to an embodiment of the present invention and the first holder 30 is provided with a plurality of optical elements 21 for converting an optical signal into an electrical signal by receiving and / or receiving the optical signal; A second holder (50) supporting one end of the plurality of optical fibers (23), a main body (40) on which the first and second holders (50) are installed, and means for limiting crosstalk between adjacent channels; It comprises a coupling means for coupling the second holder 50 with the main body 40.

The optical device 21 may include a light emitting device that emits an optical signal and / or a light receiving device that receives incident light and converts the incident light into an electrical signal. This optical element 21 has a structure arranged in an array so as to enable signal transmission of a plurality of channels, as shown.

The first holder 30 includes a base 31 on which the optical element 21 is installed, and a plurality of lead members 33 installed on the base 31 and electrically connected to the optical elements 21. Include. The first holder 30 guides the installation position of the optical device 21. The second holder 50 supports one end of the plurality of optical fibers 23 having an array structure and guides the installation position of the optical fibers 23. Here, the second holder 50 is preferably formed by a plastic injection molding method.

The main body 40 has a first mounting portion 41 to which the first holder 30 is coupled, and a second penetrating portion of the first mounting portion 41 and the second holder 50 is coupled to and installed. It has an installation part 43. The first installation part 41 so that the optical element 21 installed in the first holder 30 and the end 23a of the optical fiber 23 installed in the second holder 50 face each other at a predetermined interval. ) And the second mounting portion 43 are formed through. Guide rails 41a are formed in both sides of the first installation part 41 so that the first holder 30 is slidably coupled. Here, the main body 40 is preferably formed by a plastic injection molding method.

In the present embodiment, the means for preventing the crosstalk is the separation groove 61 formed between the optical fiber 23 of the first holder 30 and the second installation portion corresponding to the separation groove 61, respectively. The partition wall 63 formed in 43 is included. Here, the partition 63 is preferably formed extending from the main body 40.

The separation grooves 61 are formed between the optical fibers 23 supported by the first holder 30, respectively. The partition 63 is formed in the second installation part 43 to correspond to the separation groove 61 so as to be fitted into the separation groove 61 when the second holder 50 and the main body 40 are coupled to each other. do. The height h ₂ of the partition 63 is preferably larger than the depth h ₁ of the separation groove 61. In this case, the difference d between the distance between the optical element 21 and the optical fiber end 23a and the distance between the partition 63 and the optical element 21 is the height of the partition 63 and the separation groove ( 61 is the depth difference d. Therefore, the partition wall 63 is positioned to protrude further toward the optical element 21 than the optical fiber end portion 23a, so that the partition wall 63 blocks the optical signal from being transmitted to the adjacent channel. That is, in the case where the light receiving element 21 is provided as the optical element 21, the light is directed to the light receiving element located adjacent to the corresponding light receiving element 21 due to diffraction of the light at the optical fiber end 23a, that is, spreading phenomenon. To block. In addition, when the light emitting device 21 is provided as the optical device 21, the divergent light emitted from the light emitting device 21 is blocked from being incident on the optical fiber 23 adjacent to the corresponding optical fiber 23.

On the other hand, the separation groove 61 and the partition wall 63 guides the installation position of the second holder 50 when the second holder 50 and the main body 40 is coupled to the optical fiber for the optical element 21 Enable passive alignment of (23).

The coupling means includes a pair of clamping members 71 installed in the second holder 50 and coupling holes 73 formed at both side wall portions 41 of the main body 40 to couple the clamping members 71 to each other. It includes. Preferably, the clamping member 71 is elastically deformable. That is, when the second holder 50 is installed in the second mounting portion 43, the clamping member 71 is elastically deformed to slide while elastically pressing both side walls 41a of the main body 40. In addition, the clamping member 71 is elastically caught in the coupling hole 73 at a position where insertion is completed and the second holder 50 is caught by the partition 63. Therefore, the second holder 50 is coupled to the main body 40 while the optical fiber 23 is correctly aligned and coupled with respect to the optical device 21.

Meanwhile, the separating groove 61 and the clamping member 71 may be integrally formed by plastic injection molding at the time of manufacturing the second holder 50. In addition, the first and second installation parts 43, the partition 63, and the coupling hole 73 may also be integrally formed by a plastic injection molding method during the manufacturing of the main body 40.

The optical connector module according to the present invention as described above is provided in the main body corresponding to the separation groove and the separation groove of a predetermined depth formed between the optical fibers in the holder for supporting a plurality of optical fibers, when the holder and the main body when the coupling Since the partition wall is inserted into the separation groove and is positioned to protrude more than the end of the optical fiber toward the optical element installed in the main body by blocking the holder, the partition wall prevents the optical signal from being transmitted to the adjacent channel. cross talk).

In addition, the separation groove and the partition wall guide the installation position of the holder when the holder and the main body are coupled, so that passive alignment of the optical fiber with respect to the optical element is possible.

Claims (3)

An optical connector module for coupling a plurality of optical elements for emitting an optical signal and / or receiving an optical signal and converting the optical signal into an electrical signal, and a plurality of optical fibers for transmitting incident light, the optical connector module comprising: a first holder provided with the optical element; A second holder supporting one end of the optical fiber; A main body having first and second mounting portions respectively provided with the first and second holders so that the ends of the optical element and the optical fiber face each other with a predetermined distance therebetween; A separation groove formed between the optical fibers of the second holder, and a partition wall formed in the second installation part to fit into the separation groove when the second holder and the main body are coupled to each other and to block an optical signal from being transmitted to an adjacent channel. Means for limiting crosstalk between adjacent channels; And a coupling means for coupling the second holder to the main body. The clamping device of claim 1, wherein the coupling unit comprises: a clamping member installed at the second holder and capable of elastic deformation; And a coupling hole formed in the main body, the coupling hole in which the clamping member is elastically slidably coupled to the second installation unit at the time of installation of the second holder. 2. The apparatus of claim 1, wherein the first holder comprises: a base; And a plurality of lead members installed on the base and electrically connected to the optical device.