KR101944944B1 - Light transmitting/receiving module of multi channel type - Google Patents

Abstract

The present invention provides a semiconductor device comprising: a substrate; An optical element provided on the substrate; A mounting block coupled to the substrate to face the optical element; An optical fiber installed in the mounting block; A projection lens installed on the mounting block so as to face the optical element and mediating optical coupling between the optical element and the optical fiber; And an interval setting unit protruding from the mounting block toward the substrate to set a first interval between the optical element and the projection lens.

Description

[0001] LIGHT TRANSMITTING / RECEIVING MODULE OF MULTI CHANNEL TYPE [0002]

The present invention relates to a multi-channel optical T / R module.

Recently, in the case of active optical cable (AOC) such as High-Definition Multimedia Interface (HDMI), DisplayPort and DVI (Digital Visual Interface) in which demand is increasing, More than four channels are required to focus more than one wavelength.

However, most commercially available AOC cables have a structure using four or two fibers. Therefore, the cable having such a structure is disadvantageous in that it is difficult to install, maintain and repair it, and it becomes difficult to transmit the optical signal over a long distance.

In a conventional multichannel optical module capable of focusing a plurality of wavelengths on one optical fiber, a beam is reflected in a zigzag shape using a CWDM (Coarse Wavelength Division Multiplexing) filter and optically coupled. In such a case, the difference in optical path between the respective wavelengths is large, so that a conventional focusing lens can not be used, and alignment is very difficult.

It is an object of the present invention to provide a multichannel optical transceiver module that allows optical coupling between optical elements and optical fibers to be performed directly, while manual alignment between the optical elements and optical fibers can be accurately performed in a simple manner at the time of assembly.

According to an aspect of the present invention, there is provided a multi-channel optical transmission / reception module including: a substrate having a first recess portion at a center thereof; An optical element provided in the first recess portion of the substrate; A mounting block coupled to the substrate to face the optical element; An optical fiber installed in the mounting block; A projection lens installed on the mounting block so as to face the optical element and mediating optical coupling between the optical element and the optical fiber; An interval setting unit protruding from the mounting block toward the substrate, the interval setting unit being configured to set a first interval between the optical element and the projection lens to a set value by manual alignment; And a wiring disposed on the substrate so as to extend from the outside of the first recess portion into the first recess portion and electrically connecting the driving chip to the optical element, And a second lid defining a closed space together with the first recess portion, wherein the translucent lens is located in the second recess portion, and the gap setting unit is configured to contact the substrate Substrate contact protrusions; And a wiring contact protrusion protruding with a protrusion length smaller than that of the substrate contact protrusion so as to be in contact with the wiring, thereby maintaining the closed space.

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Here, the height at which the projection lens projects from the second recess portion is equal to the difference in height of the protruding portion of the optical element at the depth of the first recess portion, and the first spacing is equal to the protrusion length of the spacing setting unit It may be the same.

The alignment unit may be further configured to manually align and align the substrate and the mounting block in a state where the optical element is aligned with the projection lens.

Here, the alignment unit may include: an alignment groove formed in the substrate; And an alignment protrusion protruding from the mounting block and inserted into the alignment groove.

Here, the substrate may be a silicon optical bench (SiOB) type.

Here, the mounting block may include a seating groove partially accommodating the optical fiber, and one end of the optical fiber being caught by manual alignment at a position spaced apart from the projection lens by a second distance.

The optical fiber may further include a blocking wall provided in the mounting block corresponding to one end of the optical fiber and having an exposure hole corresponding to the core of the optical fiber.

Here, a fixing member may be further provided on the opposite side of the light-blocking lens with respect to the blocking wall, for fixing the optical fiber to the mounting block.

According to the multi-channel optical T / R module of the present invention configured as described above, the optical coupling between the optical devices and the optical fiber can be directly performed, but the passive alignment between the optical devices and the optical fibers can be accurately performed at the time of assembly.

1 is an exploded perspective view of a multi-channel optical T / R module 100 according to an embodiment of the present invention.
2 is a cross-sectional view of a multi-channel optical T / R module 100 according to the line (II-II) of FIG.
3 is an assembled perspective view of a multi-channel optical T / R module 200 according to another embodiment of the present invention.
4 is an assembled perspective view of a multi-channel optical T / R module 300 according to another embodiment of the present invention.

Hereinafter, a multi-channel optical T / R module according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. In the present specification, the same or similar reference numerals are given to different embodiments in the same or similar configurations.

1 is an exploded perspective view of a multi-channel optical T / R module 100 according to an embodiment of the present invention.

The multi-channel optical T / R module 100 includes a substrate 110, an optical device 120, a mounting block 130, an optical fiber 140, a floodlight lens 150, an interval setting unit 160, A wiring 170, and an alignment bonding unit 180. [

The substrate 110 may have a generally plate shape. One main surface 111 of the substrate 110 is arranged to face the mounting block 130. [ The first recess portion 115 may be formed at the center of the main surface 111. Thereby, the first recess portion 115 is located in the edge region of the main surface 111 along the entire circumferential direction thereof. One side 113 of the substrate 110 extends in a direction different from the main surface 111. [ The substrate 110 may be of silicon-based, silicon optical bench (SiOB) type for its components.

The optical element 120 is a structure for transmitting and receiving light. In detail, the optical element 120 may be composed of a laser diode for transmitting light and a photodiode for receiving light. The optical elements 120 may be provided in multiple numbers, and may be arranged to form one row. The optical element 120 may be mounted on the substrate 110, specifically, the first recess portion 115.

The mounting block 130 is configured to be coupled to the substrate 110 to face the optical element 120. The mounting block 130 may be a structure having a vertical portion 131 in parallel with the substrate 110 and a horizontal portion 136 extending in a different direction from the vertical portion 131. In the vertical portion 131, a receiving groove 132 for receiving the wiring 170 may be formed. The receiving grooves 132 may extend in the downward direction from the upper portion of the vertical portion 131 along the extending direction of the wiring 170. The horizontal portion 136 may be formed with a seating groove 137 partially accommodating the optical fiber 140. The seating groove 137 may extend in a direction away from the optical element 120. [ A plurality of seating grooves 137 may be formed corresponding to the number of the optical fibers 140. The optical fiber 140 mounted on the seating groove 137 maintains the second gap D ₂ (see FIG. 2) with the projection lens 150.

The optical fiber 140 is optically coupled to the optical element 120 through the projection lens 150. The optical fiber 140 is composed of a core 145 for transmitting light and a cladding 146 in the form of a pipe for wrapping the core 145 and totally reflecting the light incident through the core 145 toward the core 145 . 2) of the end portion of the seating groove 137 and the core 145 corresponds to the projection lens 150. The optical fiber 140 is fixed to the seating groove 137, .

The projection lens 150 is a structure for optically coupling the optical element 120 and the optical fiber 140. To this end, the projection lens 150 may be mounted on the mounting block 130, specifically, the vertical portion 131. The light projecting lens 150 may have a width larger than the width of the vertical portion 131 so as to protrude from both sides of the vertical portion 131. A plurality of light projecting lenses 150 are provided corresponding to the respective optical elements 120 (or the optical fibers 140).

The spacing setting unit 160 is configured to maintain a first spacing D ₁ (see FIG. 2) between the optical element 120 and the floodlight lens 150 when the substrate 110 and the mounting block 130 are coupled to be. The interval setting unit 160 is formed to protrude from the mounting block 130, specifically, the vertical portion 131 toward the substrate 110.

The wiring 170 is provided on the surface of the substrate 110 to connect the driving chip (not shown) and the optical device 120. Accordingly, a signal generated by the driving chip may be input to the optical device 120, or a signal input to the optical device 120 may be transmitted to the driving chip. These wirings may extend outside the first recess portion 115, specifically, from the side surface 113 into the first recess portion 115. The driving chip connected to the wiring 170 may be mounted on a heat sink (not shown) attached to the other main surface of the substrate 110. Further, the driving chip may be connected to another controller (not shown) by a flexible circuit board (FPCB).

The alignment coupling unit 180 is configured to couple the substrate 110 and the mounting block 130 in a state where the optical element 120 and the projection lens 150 are aligned. Specifically, the aligning / combining unit 180 may have an aligning projection 181 and an aligning groove 185. [ The alignment protrusions 181 protrude in the direction toward the substrate 110 from the mounting block 130, specifically, the vertical portion 131. The alignment groove 185 is formed in the substrate 110 to receive the alignment protrusion 181 and to engage with the alignment protrusion 181. The alignment protrusions 181 and the alignment grooves 185 are at least two sets and four sets in this embodiment. Four sets of the alignment protrusions 181 and the alignment grooves 185 may be located outside the first recess portion 115. The substrate 110 is advantageous in that the alignment groove 185 can be precisely formed without breaking the alignment groove 185 by the silicon component in the case of the silicon optical bench (SiOB) type.

According to this configuration, when the substrate 110 and the mounting block 130 are coupled, the gap between the optical element 120 and the projection lens 150 can be set to a precisely set size by the gap setting unit 160 . Also, when the optical fiber 140 is installed in the mounting block 130, the distance between the light transmitting lens 150 and the optical fiber 140 can be set accurately.

Further, since the coupling between the substrate 110 and the mounting block 130 is performed by the alignment coupling unit 130, when the substrate 110 is accurately aligned in the left / right / up / down direction with respect to the mounting block 130 Lt; / RTI > Thereby, the alignment between the optical element 120 and the projection lens 150, and the alignment between the wiring 170 and the receiving groove 132 can be automatically and accurately achieved.

The above-described interval setting and alignment relationship will be further described with reference to FIG.

2 is a cross-sectional view of a multi-channel optical T / R module 100 according to the line (II-II) of FIG.

Referring to FIG. 2, a second recess 135 may be formed on a major surface of the mounting block 130 facing the substrate 110. The second recess 135 is a portion defined by the relative concavity by the spacing setting unit 160 being protruded from the mounting block 130. And the projection lens 150 is positioned on the second recess 135. [ The second recess portion 135 faces the first recess portion 115 and can form a closed space C together therewith. The light travels from the optical element 120 to the projection lens 150 or from the projection lens 150 to the optical element 120 in the closed space C.

The interval setting unit 160 is configured to protrude in a ring shape so as to surround the second recess portion 135. The gap setting unit 160 may be divided into a substrate contact protrusion 161 that contacts the substrate 110 and a wiring contact protrusion 165 that contacts the wiring 170. [ At this time, the interval between the optical element 120 and the projection lens 150 becomes the first interval D ₁ . The height b at which the projection lens 150 protrudes from the second recess 135 depends on the height of the optical element 120 protruding from the depth a ₁ of the first recess 115 a < ₂ >). Therefore, the first interval D ₁ is equal to the projection length of the interval setting unit 160, specifically, the projection length P ₁ of the substrate contact projection 161. Thus, in order to set a first distance (D _1), it is provided with a simplicity which when set equal to only the desired first distance (D _1), the protruding length (P ₁₎ of the substrate contact projection 161. The In addition, the thickness of the wiring 170 is added to the protruding length P ₂ of the wiring contact protruding portion 165 to correspond to the first gap D ₁ . This is because the protruding length P ₂ of the wiring contact protruding portion 165 is smaller than the protruding length P ₁ of the substrate contacting protruding portion 161 by the thickness of the wiring 170.

The second gap D ₂ between the light projecting lens 150 and the optical fiber 140 can be set to a value automatically set by properly installing the optical fiber 140 in the seating groove 137. Specifically, one end 141 of the optical fiber 140 can be pushed to the stopping jaw 137a, which is one end of the optical fiber 140 while being inserted into the seating groove 137. [ As a result, when the one end 141 of the optical fiber 140 is stopped by being caught by the engagement protrusion 137a, the optical fiber 140 is automatically separated from the light transmission lens 150 by the second gap D ₂ . The second gap D ₂ is a distance from the vertical portion 131 to the projection length L of the projection lens 150 at a distance F from the vertical portion 131 to the one end portion 141 of the optical fiber 140 Is subtracted.

Next, other types of multi-channel optical T / R modules 300 and 400 will be described with reference to FIGS. 3 and 4. FIG.

3 is an assembled perspective view of a multi-channel optical T / R module 200 according to another embodiment of the present invention.

The multi-channel optical T / R module 200 is substantially the same as the multi-channel optical T / R module 100 of the previous embodiment, but includes a blocking wall 290 and a fixing member 295.

The blocking wall 290 is mounted on the horizontal portion 236 of the mounting block 230. Specifically, the blocking wall 290 is protruded to surround the optical fiber 240 housed in the seating groove 237 in the horizontal portion 236. A portion of the blocking wall 290 corresponding to the one end 241 of the optical fiber 240 is formed with an exposure hole 291. This exposure hole 291 exposes the core 245 of the optical fiber 240 and allows light to travel from the floodlight 250 to the core 245.

The fixing member 295 is configured to fix the optical fiber 240 to the horizontal portion 236 of the mounting block 230. The fixing member 295 is located on the opposite side of the projection lens 250 with respect to the blocking wall 290. Specifically, the fixing member 295 may be, for example, an epoxy cured by being poured. This epoxy does not flow out of the region defined by the blocking wall 290 by the blocking wall 290 and the optical fiber 240.

The fixing member 295 may be fixed to the mounting block 230 while the fixing member 295 may flow into the light transmitting lens 250 and the optical fiber 240 so that the distance between the light transmitting lens 250 and the optical fiber 240 Optical coupling is not disturbed.

4 is an assembled perspective view of a multi-channel optical T / R module 300 according to another embodiment of the present invention.

Referring to FIG. 3, the multi-channel optical T / R module 300 is substantially the same as the previous embodiment, except that the blocking wall 290 is not provided and the fixing member 395 is different from the previous one.

Specifically, the fixing member 395 is a structure in which a fluid material such as epoxy is not a cured structure but a solid body itself. Thus, it does not require the blocking walls 290 required in the case of the preceding epoxy.

The fixing member 395 is placed on the horizontal portion 336 so that the optical fiber 340 is brought into close contact with the horizontal portion 336. A fixing protrusion 396 may protrude from the fixing member 395. The fixing protrusion 396 is inserted into the fixing groove 338 formed in the horizontal portion 336 so that the fixing member 395 does not shake or move in the horizontal direction in the correct position.

The multi-channel optical T / R module is not limited to the configuration and operation of the embodiments described above. The embodiments may be configured so that all or some of the embodiments may be selectively combined so that various modifications may be made.

100, 200, 300: Multichannel optical transmission / reception module 110, 210, 310:
120: Optical element 130,230,330: Mounting block
140,240,340: Optical fiber 150,250,350: Projection lens
160, 360, 360: interval setting unit 170, 270,
180: alignment bonding unit 290: blocking wall

Claims (11)

A substrate having a first recessed portion at a center thereof;
An optical element provided in the first recess portion of the substrate;
A mounting block coupled to the substrate to face the optical element;
An optical fiber installed in the mounting block;
A projection lens installed on the mounting block so as to face the optical element and mediating optical coupling between the optical element and the optical fiber;
An interval setting unit protruding from the mounting block toward the substrate, the interval setting unit being configured to set a first interval between the optical element and the projection lens to a set value by manual alignment; And
And a wiring disposed on the substrate so as to extend from the outside of the first recess portion into the first recess portion to electrically connect the driving chip to the optical element,
The mounting block includes:
And a second recess portion defined by the gap setting unit and forming a closed space together with the first recess portion,
Wherein the projection lens is located in the second recess portion,
Wherein the interval setting unit comprises:
A substrate contact protrusion contacting the substrate; And
And a wiring contact protrusion protruding at a protrusion length smaller than the substrate contact protrusion so as to be in contact with the wiring, the wiring contact protrusion maintaining the closed space.
delete delete delete The method according to claim 1,
The height of the projection lens protruding from the second recess portion is equal to the height of the protruded height of the optical element at the depth of the first recess portion so that the first spacing is equal to the projection length of the spacing setting unit In multi-channel optical transceiver module.
The method according to claim 1,
Further comprising an alignment coupling unit configured to allow the optical element to manually align and align the substrate and the mounting block in alignment with the light projecting lens.
The method according to claim 6,
The alignment coupling unit includes:
An alignment groove formed in the substrate; And
And an alignment protrusion protruded from the mounting block and inserted and coupled to the alignment groove.
8. The method of claim 7,
Wherein:
Silicon Optical Bench (SiOB) type multichannel optical transceiver module.
The method according to claim 1,
The mounting block includes:
And a seating groove partially receiving the optical fiber and being engaged by manual alignment at a position where one end of the optical fiber is spaced apart from the projection lens by a second interval.
10. The method of claim 9,
Further comprising a blocking wall mounted on the mounting block corresponding to one end of the optical fiber and having an exposure hole corresponding to a core of the optical fiber.
11. The method of claim 10,
Further comprising a fixing member disposed on the opposite side of the projection lens with respect to the blocking wall, for fixing the optical fiber to the mounting block.

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