KR102572335B1 - optical subassembly - Google Patents

Abstract

The present invention relates to an optical subassembly, and relates to a first accommodating part formed with a first accommodating groove having an open top so that a ferrule of an optical connector protrudes therein and having an optical fiber embedded therein, and a first accommodating part of the first accommodating part. A spaced portion extending downward from a through hole formed vertically in the center of the bottom surface of the receiving groove and having a spaced space communicating with the through hole, and extending downward from the spaced part but having an inner diameter larger than the spaced space, and the lower part is A housing including a mounting portion having an open mounting space, a laser diode mounted in the mounting space of the mounting portion and emitting light in a direction toward the through hole, and transmitting light emitted from the laser diode to the optical fiber in the ferrule through the through hole. A lens module having a focusing lens for convergence and a support body supporting the focusing lens and mounted in a mounting space of a mounting portion is provided. According to such an optical subassembly, the light coupling efficiency of the light emitted from the laser diode to the optical fiber to be connected is improved, and heat dissipation can be improved.

Description

Optical subassembly {optical subassembly}

The present invention relates to an optical subassembly, and more particularly, to an optical subassembly capable of transmitting light emitted from a laser diode through an optical connector.

In general, an optical transmission/reception module refers to a module that accommodates various optical communication functions in one package and enables connection with an optical fiber. Optical transmitters are variously disclosed, such as Korean Patent Registration No. 10-0492846.

On the other hand, recently, an optical transmitter using a laser diode that consumes less power and can be used for a long distance as a light source is used in various fields other than communication purposes. In addition, there is a steady demand for a structure capable of improving light coupling efficiency for transmission of light emitted from a high-power laser diode to an optical fiber and improving connection convenience.

The present invention was invented to solve the above requirements, and an object of the present invention is to provide an optical subassembly capable of improving heat dissipation while improving the coupling efficiency of light emitted from a laser diode to an optical fiber to be connected.

In order to achieve the above object, an optical subassembly according to the present invention includes a first accommodating part formed with a first accommodating groove having an open top so that the ferrule of an optical connector protrudes, and a ferrule in which an optical fiber is embedded; A spaced portion extending downward from a through hole vertically formed in the center of the bottom surface of the first accommodating groove of the first accommodating portion and having a spaced space communicating with the through hole, and extending downward from the spaced portion to the spaced space a housing having a larger inner diameter and including a mounting portion having a mounting space with an open bottom; a laser diode mounted in the mounting space of the mounting portion and emitting light in a direction toward the through hole; A lens module having a focusing lens for concentrating the light emitted from the laser diode to the optical fiber in the ferrule through the through hole, and a support body supporting the focusing lens and mounted in the mounting space of the mounting part.

In addition, the separation space formed in the separation portion includes a first vertically extending portion extending vertically from the upper end of the mounting space of the mounting portion, an inclined portion having an inner diameter gradually narrowed at the upper end of the first vertical extension portion, and the A second vertically extending portion extending vertically from an upper end of the inclined portion and communicating with the through hole may be formed.

Preferably, a thread is formed on an outer circumferential surface of the first accommodating portion along a longitudinal direction so as to be screwed with the optical connector.

In addition, the optical fiber may be a multimode optical fiber, and the focusing lens may be an aspherical lens that focuses the light emitted from the laser diode to the multimode optical fiber through the through hole.

In addition, the main mounting portion corresponding to the lower region of the mounting space and forming a main space in which the laser diode is press-fitted and mounted; It is formed to have a sub-space having an inner diameter smaller than that of the main space of the main mounting portion and has a sub-mounting portion to which the lens module is bonded with an adhesive, and the housing has heat dissipation efficiency generated by the laser diode. In order to increase the , it is applied that is formed of a metal material.

According to the optical subassembly according to the present invention, the optical coupling efficiency of the light emitted from the laser diode to the optical fiber to be connected is improved while providing the advantage of improving heat dissipation.

1 is a perspective view showing an optical subassembly according to the present invention separated together with an optical connector;
2 is a cross-sectional view of a separated state of the optical subassembly and the optical connector of FIG. 1;
FIG. 3 is a cross-sectional view of a coupled state of the optical subassembly of FIG. 2 and an optical connector.

Hereinafter, an optical subassembly according to a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a perspective view showing an optical subassembly according to the present invention separated together with an optical connector, FIG. 2 is a cross-sectional view of a state in which the optical subassembly and optical connector of FIG. 1 are separated, and FIG. 3 is an optical subassembly of FIG. 2 This is a cross-sectional view of the assembly and the optical connector's combined state.

Referring to FIGS. 1 to 3 , the optical subassembly 100 according to the present invention can be coupled to and separated from the optical connector 200 by screwing.

The optical subassembly 100 includes a housing 110 , a laser diode 150 , and a lens module 160 .

The housing 110 has a structure capable of transmitting light to the optical fiber 210 of the coupled optical connector 200 while supporting the mounting of the laser diode 150 and the lens module 160 .

Here, the optical fiber 210 applied to the optical connector 200 is a multimode optical fiber.

In addition, the optical connector 200 has an optical fiber 210 embedded in the center and is movable along a connection body 225 supporting a ferrule 220 extending to protrude outward, and a thread is formed on the inner circumferential surface of the housing 110. It is applied that has a structure having a coupling nut 230 that is screwed with.

The housing 110 is divided into a first accommodating part 112, a spaced part 114, and a mounting part 116 in the longitudinal direction.

The first accommodating part 112 has a first accommodating groove 112a with an open top so that the ferrule 220 of the optical connector 200 protrudes and enters. Part.

A thread 113 is formed on the outer circumferential surface of the first accommodating portion 112 along the longitudinal direction so as to be screwed with the optical connector 200 .

The separation portion 114 extends downward from a through hole 112b vertically formed in the center of the bottom surface of the first accommodating groove 112a of the first accommodating portion 112 and communicates with the through hole 112b. It is a part formed with (115).

A portion of the spaced portion 114 in contact with the lower end of the first accommodating portion 112 is formed to have an outer diameter larger than that of the first accommodating portion 112 .

The separation space 115 formed in the separation portion 114 provides a waveguide path of light, and an appropriate length is applied to correspond to the focal length of the focusing lens 161 described later.

Here, if the separation portion 114 is divided along the longitudinal direction according to the shape of the separation space 115, the first vertically extending portion 114a extending vertically from the top of the mounting space 116a of the mounting portion 116 and , the inclined portion 114b having a gradually narrower inner diameter at the upper end of the first vertically extending portion 114a, and the second vertically extending portion extending vertically from the upper end of the inclined portion 114b and communicating with the through hole 112b. It is formed with a portion 114c. This separation space 115 also serves to guide the convergence of light.

The mounting portion 116 extends downward from the spaced portion 114 and has an inner diameter larger than the spaced space 115 and is formed to have a mounting space 116a with an open bottom.

If the mounting portion 116 is divided along the longitudinal direction, the main mounting portion 118 corresponds to the lower area of the mounting space 116 and forms the main space in which the laser diode 150 is press-fitted and mounted, and the main firewood portion It is formed to have a sub-space having a smaller inner diameter than the main space of (118) and to have a sub-mounting portion 117 to which the lens module 160 is bonded with adhesive.

On the other hand, the outer shape of the spaced part 114 and the mounting part 116 of the housing 110 may be formed to have a jaw part having a different outer diameter along the longitudinal direction according to the required shape such as coupling with the mounting object, as well as am.

The housing 110 is formed of a metal material, for example, stainless steel, in order to increase the heat dissipation efficiency generated by the laser diode 150.

The laser diode 150 is press-fitted into the main space of the main mounting portion 117 and emits light in a direction toward the through hole 112b.

The laser diode 150 is formed in a Thio-can type.

The lens module 160 includes a focusing lens 161 that focuses light emitted from the laser diode 150 to the optical fiber 210 in the ferrule 120 through the through hole 112b, and an edge of the focusing lens 161. It supports and has a structure having a support body 162 mounted in the sub space of the sub mounting portion 117.

The focusing lens 161 is an aspherical lens that focuses light emitted from the laser diode 150 on the multimode optical fiber 210 through the through hole 112b. Here, the focusing lens 161 is formed in an aspherical shape through a design process capable of measuring the divergence of the light beam emitted from the laser diode 150 and improving the focusing efficiency from this to the multimode optical fiber 210. You can apply it.

The support body 162 is bonded with an adhesive such as epoxy.

In this optical subassembly 100, the ferrule 220 of the optical connector 200 is inserted into the first accommodating groove 112a of the first accommodating portion 112, and the coupling nut 230 is inserted into the first accommodating portion. When screwed into the outer circumferential surface of 112, the light transmission connection is completed, and the light emitted from the laser diode 150 is focused on the focusing lens 161 and is incident through the tip of the optical fiber 210 in the ferrule 220. .

The optical subassembly 100 described above provides an advantage of improving heat dissipation while improving optical coupling efficiency of light emitted from the laser diode 150 to the optical fiber 210 to be connected.

110: housing
150: laser diode
160: lens module

Claims (5)

A first accommodating part formed with a first accommodating groove having an open top so that the ferrule of the optical connector protrudes and is formed to protrude, and perpendicular to the center of the bottom surface of the first accommodating groove of the first accommodating part. A mounting space extending downward from the upper through hole and having a spaced space communicating with the through hole, and a mounting space extending downward from the spaced part but having an inner diameter larger than the spaced space and having an open bottom. a housing comprising a portion;
a laser diode mounted in the mounting space of the mounting portion and emitting light in a direction toward the through hole;
A lens module having a focusing lens for concentrating the light emitted from the laser diode to an optical fiber in the ferrule through the through hole, and a support body supporting the focusing lens and mounted in the mounting space of the mounting part,
The separation space formed in the separation portion includes a first vertically extending portion extending vertically from the upper end of the mounting space of the mounting portion, an inclined portion having an inner diameter gradually narrowed at the upper end of the first vertical extending portion, and the inclined portion. It extends vertically from the upper end of and is formed to have a second vertically extending portion communicating with the through hole,
A thread is formed on the outer circumferential surface of the first accommodating portion along the longitudinal direction so as to be screwed with the optical connector,
The optical fiber is a multimode optical fiber,
The focusing lens is an aspherical lens for concentrating the light emitted from the laser diode into the multimode optical fiber through the through hole.
The mounting part
a main mounting part corresponding to a lower area of the mounting space and forming a main space in which the laser diode is press-fitted and mounted;
It is formed to have a sub-space having a smaller inner diameter than the main space of the main mounting portion and to have a sub-mounting portion to which the lens module is bonded with an adhesive,
The optical sub-assembly, characterized in that the housing is formed of a metal material to increase the heat dissipation efficiency generated by the laser diode.


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