KR100493440B1 - High density optical fiber array block and fabrication thereof - Google Patents

Abstract

The present invention relates to a high-density optical fiber array block and a manufacturing method, and more particularly, in the high-density optical fiber array block using a V-groove, the center portion and the edge of the glass cover and the V-groove block are grooved to a predetermined depth by a sandblasting method. It is to improve the stability of the optical fiber alignment process and durability of the high-density optical fiber array block by forming a.

The high-density optical fiber array block of the present invention comprises a glass cover plate to a certain depth in the center portion and the edge portion using a sand blaster processing method; The technical features are that the edge portion is dug to a certain depth, and the adhesive is inserted between the glass cover and the V-groove and the V-groove block having the plate V-groove by the KOH wet etching method.

Therefore, the high-density optical fiber array block and the manufacturing method of the present invention by processing a central portion of the glass cover in contact with the optical fiber array in a high-density optical fiber array block by a sandblasting method to a certain depth in parallel when the cover and the V-groove block are combined By minimizing the deviation from the optical fiber array can be stably fixed to the V-groove, and also by reducing the distance between the glass cover and the V-groove block has the advantage of reducing the amount of adhesive used for bonding.

  In addition, by sandblasting the surface of the glass cover and the edge portion of the V-groove block to increase the surface roughness, the area that the adhesive touches per unit area increases, thereby increasing the adhesive force between the glass cover and the V-groove block to increase external adhesion or There is an effect that a high-density optical fiber array block that is more durable to vibration can be manufactured.

Description

High density optical fiber array block and fabrication

The present invention relates to a high-density optical fiber array block and a manufacturing method, and more particularly, in the high-density optical fiber array block using the V-groove, the center portion and the edge of the glass cover and the V-groove block are sandblasted. It is to improve the stability of the optical fiber alignment process and the durability of the high-density optical fiber array block by forming the groove to a certain depth.

Conventionally, precise alignment is made by using silica or silicon to precisely align the optical fibers by making precise V-grooves by machining or by using a potassium hydroxide wet etching method, and then aligning the optical fibers therewith. The prepared optical fiber array block.

1 is a cross-sectional view of a conventional optical fiber array block. As shown in FIG. 1, when processing the V-grooves 4 such that the central axis spacings of the optical fibers 2 to be aligned are 250 μm, the central axis of the optical fiber 2 is located inside the V-groove 4. There is an advantage that the machining of the V-groove to be located enough, but it is difficult to change the shape of the V-groove.

Therefore, the optical fibers 2 arranged in the V-groove 4 are stably aligned inside the V-groove 4 by external shaking, impact, etc., and the optical fibers 2 are formed in the V-groove using a flat cover. (4) It is fixed and aligned inside.

In addition, the V-groove block (3) and the glass cover (1) are bonded to each other using a thermal or ultraviolet adhesive (5) between the V-groove block (3) with the optical fiber (2) aligned and the glass cover (1). The fixed optical fiber array was fixed.

2 is a cross-sectional view of a typical optical fiber array block. In the optical fiber array block, as shown in FIG. 2, when the distance between the optical fibers 2 is narrowed from 250 μm to 127 μm, the center of the optical fiber is not located inside the V-groove 4, but is located upwards. Vibration or shaking results in an unstable state in which the optical fibers may deviate or deviate from the V-groove 4.

In addition, since the optical fiber 2 is located above the V-groove 4, the gap between the V-groove block 3 and the glass cover 1 is increased, thereby increasing the amount of expensive adhesive and increasing the unevenness of the glass cover 1. When the optical fibers 2 are pressed at a pressure, the optical fibers are in an unstable state from which the V-grooves 4 can escape.

In addition, the gap between the glass cover 1 and the V-groove block 3 increases, so that the consumption of expensive heat or ultraviolet adhesive 5 is increased, thereby increasing the manufacturing cost of the optical fiber array block. .

Accordingly, the present invention is to solve the above disadvantages and problems of the prior art, by digging the glass cover portion which is in contact with the optical fibers to a certain depth in the manufacturing of high-density optical fiber array block between the glass cover and the V-groove block. By narrowing the gaps, the unstable condition is eliminated during fiber alignment, and the surface roughness of the edges of the V-groove block and the glass cover is increased to increase the adhesion of the V-groove block and the glass cover to the adhesive, resulting in higher durability. It is an object of the present invention to fabricate an optical fiber array block.

The object of the present invention is to use a sandblasting method, plated glass cover the middle portion and the edge portion to a predetermined depth; It is achieved by a V-groove block having a plate V-groove and a high density optical fiber array block and a fabrication method in which an edge is inserted into a predetermined depth and an adhesive is inserted between the glass cover and the V-groove by KOH wet etching method. do.

Optical devices such as wavelength division multiplexing (WDM) and optical splitters have been developed in order to increase the amount of optical transmission, and in order to reduce the size of such optical devices, designs and fabrications are made with smaller spacing between the waveguides. ought. Therefore, in order to allow the multi-channel photons and the optical fiber array block to be connected, the spacing between the optical fibers arranged in the optical fiber array block must be designed and manufactured to be accurately aligned with the waveguide spacing of the optical device. Therefore, gradually, the spacing between optical fibers in the optical fiber array block requires high density optical fiber array blocks having a spacing of 127 μm from 250 μm.

Details of the above object and technical configuration of the present invention and the effects thereof according to the present invention will be more clearly understood by the following detailed description with reference to the drawings showing preferred embodiments of the present invention.

First, Figure 3 is a cross-sectional view of the optical fiber array block according to the present invention. As shown in FIG. 3, by processing a portion of the glass cover 20 to which the optical fiber 30 touches to a certain depth, the gap between the glass cover 20 and the V-groove block 40 is narrowed to stably maintain the optical fiber 30. Align and fix them, and reduce the use of the adhesive, and also increase the surface roughness on the edges of the glass cover 20 and the V-groove block 40 to increase the contact area of the adhesive 60 to increase the adhesive strength and durability. A large fiber array block is proposed.

Referring to Figure 3, the glass cover 20 is the center portion and the edge portion is dug to a certain depth, the V-groove block 40 is the edge portion is dug to a certain depth and the adhesive 60 is the glass cover 20 And the V-groove 50. The center portion of the glass cover 20 is a portion in which the optical fiber array touches, and is excavated to a predetermined depth using a sandblasting method.

The predetermined depth is sold to have a gap between the V-groove block 40 in which the optical fiber 30 is aligned and the glass cover 20 do not touch each other when they are bonded. The edge portion of the glass cover 20 uses a sandblasting method.

In addition, the edge portion of the glass cover 20 and the edge portion of the V-groove block 40 have the same size and the same position. The portion of the edge of the V-groove block 40 uses a sandblasting method.

The distance between the glass cover 20 and the V-groove block 40 can be made smaller by digging the center portion of the glass cover 20 to a predetermined depth by the sand blasting method to fix the optical fibers 30. The optical fiber 30 that is unstable over the V-groove can be more stably fixed to the V-groove 50, and the splicing can be reduced by reducing the gap between the glass cover 20 and the V-groove block 40. It is possible to reduce the amount of the adhesive 60 to be used in.

3 and 4 in the center portion of the glass cover 20 in contact with the optical fibers 30 aligned in the V-groove is uniformly processed to a certain depth using a sandblasting method. The sandblasting method is a useful method for processing glass, and the surface roughness and flatness of the processed surface can be controlled by controlling the size and processing conditions of the particles used in the processing.

When the glass cover 20 processed by the sandblasting method is combined with the V-groove block 40 in which the optical fibers 30 are aligned, the optical fibers 30 are covered by the processed depth of the glass cover 20. Thus, the gap between the glass cover 20 and the edge of the V-groove block 40 can be narrowed. This can minimize the degree of deviation of the parallel when the glass cover 20 and the V-groove block 40 are coupled.

Therefore, the optical fibers 30 can be more stably fixed to the V-groove 50. In addition, by reducing the gap between the glass cover 20 and the V-groove block 40 it is possible to reduce the amount of adhesive used for bonding. Adhesives used to fabricate optical fiber array blocks are expensive because they are manufactured strictly to meet the reliability tests of the optical component telcodia standard. Therefore, reducing the use of the adhesive used in fabricating the optical fiber array block is a factor that can lower the cost of the optical fiber array block.

According to the present invention, a method for fabricating a high-density optical fiber array block includes fixing a fiber in a V-groove block in which an optical fiber central axis is placed on a V-groove, and processing a glass cover to close the gap between the V-groove block and the glass cover, and the adhesive strength of the adhesive Processing the edge surface of the V-groove block to increase the thickness, processing the glass cover edge surface to increase the adhesion of the adhesive, and inserting the adhesive in the entirety between the V-groove block and the glass lid.

4 is a configuration diagram of an optical fiber array block according to the present invention, and FIG. 5 is a precision of the glass cover processing surface of FIG. 4. As shown in FIG. 5, the glass cover uses a glass material through which ultraviolet light can transmit for curing the ultraviolet adhesive.

V-groove blocks can be fabricated using quartz or silicon, and silicon V-groove blocks using KOH wet etching are generally known to have better V-groove accuracy than quartz V-groove blocks using machining.

6 is the precision of the V-groove block machining surface of FIG. Referring to Figure 6 in Figure 4 sandblasting method of the edge portion of the glass cover and the V-groove block and the edge portion of the glass cover and the V-groove block V-groove is formed to increase the adhesive strength when bonding using the adhesive between the glass cover and the V-groove block. By increasing the surface roughness of this part by processing the surface, the adhesive force can be increased by increasing the area of contact of the adhesive per unit area.

7 is a graph measured using a surface morphometer after the actual sand blaster processing, it can be seen that the surface roughness is irregularly large. 8 is a state diagram according to the case where sandblasting process is performed or not. Therefore, when the bonding between the glass cover and the V-groove block using an adhesive to increase the surface roughness as shown in Figure 7 and 8 (a), between the flat cover and the V-groove block as shown in Figure 8 (b) In the case of bonding using an adhesive, the bonding force is increased because the area of the adhesive contacted per unit area is larger. Therefore, the increase in adhesion between the glass cover and the V-groove block as shown in FIGS. 5 and 6 allows the fabricated high-density optical fiber array block to have greater durability such as external shock or vibration.

Therefore, the high-density optical fiber array block and the manufacturing method of the present invention in the high-density optical fiber array block in the parallel state when the center portion of the glass cover in contact with the optical fiber array by the sandblasting method to a certain depth by combining the cover and the V-groove block By minimizing the deviation, the optical fiber array can be stably fixed to the V-groove, and the gap between the glass cover and the V-groove block can be reduced to reduce the amount of adhesive used for bonding.

In addition, by sandblasting the surface of the glass cover and the edge portion of the V-groove block to increase the surface roughness, the area that the adhesive touches per unit area increases, thereby increasing the adhesive force between the glass cover and the V-groove block to increase external adhesion or There is an effect that a high-density optical fiber array block that is more durable to vibration can be manufactured.

1 is a cross-sectional view of a conventional optical fiber array block (250 micrometers of central axis spacing between optical fibers)

Fig. 2 is a cutaway view of a typical optical fiber array block (127 micrometers of central axis spacing between optical fibers).

3 is a cross-sectional view of the optical fiber array block according to the present invention.

4 is a block diagram of an optical fiber array block according to the present invention.

It is the precision of the glass lid processing surface of FIG.

6 is the precision of the V-groove block machining surface of FIG.

7 is a graph measured using a surface morphometer after the actual sand blaster processing.

8 is a state diagram according to whether or not to perform a sand blaster process.

<Description of Signs of Major Parts of Drawings>

           10. Groove 20. Glass Cover

           30. Fiber Optic 40. V-groove Block

           50.V-groove 60.Adhesive

Claims (10)

An optical fiber block for an optical element-optic fiber interconnect, A glass cover plate 20 having a predetermined depth between the center portion and the edge portion using the sandblasting method; A V-groove block 40 in which the edge portion is dug to a certain depth and provided with a plate V-groove by a KOH wet etching method; And High density optical fiber array block characterized in that the adhesive is inserted between the glass cover (20) and the V-groove (50). The method of claim 1, The central portion of the glass cover 20 is a high density optical fiber array block, characterized in that the optical fiber array is in contact with. delete The method of claim 1, The glass cover 20 and the predetermined depth of the V-groove block 40 have a gap that does not contact each other when the V-groove block 40 and the glass cover 20 where the optical fiber 30 is aligned are bonded to each other. A high density optical fiber array block, characterized in that excavated. delete The method of claim 1, Edge portion of the glass cover (20) and the V-groove block (40) has the same size and the same position, characterized in that the high density optical fiber array block. The method of claim 1, The edge portion of the V-groove block 40 is a high-density optical fiber array block to increase the surface roughness by increasing the surface roughness by using a sandblasting method. delete The method of claim 1, The glass cover 20 is a method of manufacturing a high-density optical fiber array block, characterized in that the glass that can transmit ultraviolet rays. A method of fabricating an optical fiber block for an optical device-optic fiber interconnect, Glass cover 20 for fixing the optical fiber 30 and narrowing the gap between the V-groove block 40 and the glass cover 20 in the V-groove block 40 in which the optical fiber central axis is placed on the V-groove 50. Processing the; Machining the edge surface of the V-groove block 40 to increase the adhesion of the adhesive 60; Machining the edges of the glass lid 20 to increase the adhesion of the adhesive 60; And Method for producing a high-density optical fiber array block, comprising the step of inserting the adhesive (60) in the whole between the V-groove block (40) and the glass cover (20).