KR100277354B1 - Optical fiber array block - Google Patents

Abstract

The present invention provides an optical fiber array block coupled to the input and output optical waveguide of the optical waveguide device, the optical fiber array block is composed of optical fibers, each optical fiber array having a coating removed by a predetermined length; A front end portion coupled to the input and output optical waveguide of the optical waveguide element and having one groove having one portion of the optical fiber array in which the coating of the optical fiber array has been removed, and one having a width wider than the width of the groove of the front end portion. It is provided with a groove in which the coated end of the optical fiber array of the coated optical fiber array is located, the front end and the rear end, and the tapered shape so as to gradually change from the width of the groove of the front end to the width of the groove of the rear end A basic block having a structure in which the optical fiber array is mounted and having a connection portion in which the remaining optical fiber array portion from which the coating of the optical fiber array is removed is mounted; An optical fiber fixing block for fixing an optical fiber portion from which the coating is removed among the optical fiber arrays mounted on the basic block; And an epoxy fixing the optical fiber array portion located at the connection part of the basic block, and the optical waveguide device chip is reduced by reducing the optical fiber spacing of 250 μm to 1/2 of 125 μm used in the conventional optical fiber array block manufacturing. The size of the optical waveguide device can be drastically reduced by reducing the length of the bending optical waveguide region necessary to secure the spacing between the input and output waveguides.

Description

Optical fiber array block

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical fiber array block used when an optical fiber is aligned and coupled to an input / output optical waveguide of an integrated optical device fabricated by integrating an optical waveguide device having various functions on a flat substrate on a single substrate. An optical fiber array block for miniaturizing an optical waveguide chip.

Conventional structures and fabrication methods of an optical fiber array block fabricated to attach an optical fiber to an optical waveguide device generally use a method of fixing a circular optical fiber by using a V-shaped groove, and a gap between the optical fibers. It is made to be 250㎛ the diameter of the coated optical fiber. In this case, the optical fiber mounted in the V-groove is mounted with a 125 μm diameter to the clad by removing the coating.

In general, since the optical fiber array block has a 250 µm spacing between optical fibers, the optical waveguide device should have a 250 µm spacing between the input and output portions to be combined with the optical fiber. The structure of the optical waveguide device is long in length and width of about 1000: 1, and in order to reduce the bending loss in the optical waveguide, the transition in the width direction of the waveguide must be smaller than the traveling direction. Usually, the transition angle of the waveguide is produced at 1 ° or less. Therefore, in order to manufacture the input / output optical waveguides having a 250 μm interval, a curved waveguide region connecting the optical waveguide and the input / output waveguide of the main functional part in addition to the main functional part of the waveguide element is required. The length of the optical waveguide device due to the addition of the curved waveguide has a problem in that it increases in series as the number of input and output increases.

The technical problem to be achieved by the present invention is to provide an optical fiber array block in which the optical fiber array block is arranged in a form in which the optical fibers are arranged without gaps to reduce the size of the optical waveguide chip to the interval between the optical fibers of the optical fiber array block to 125㎛ of the clad diameter of the optical fiber. will be.

1A, 1B and 1C show a plan view, side view and front view of an optical fiber array block according to the present invention.

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

100: coated optical fibers, 110: block for fixing the optical fiber

120: basic block for mounting optical fiber, 130: optical fiber with coating

140: epoxy, 102: front end of the basic block

104: connection of the basic block, 106: rear end of the basic block

According to the present invention for solving the technical problem, the optical fiber array block coupled to the input and output optical waveguide of the optical waveguide device,

An optical fiber array, the optical fiber array having a coating removed from the optical fiber by a predetermined length; A front end portion coupled to an input / output optical waveguide of the optical waveguide device, having one groove and having a portion in which the portion of the optical fiber array from which the coating of the optical fiber array has been removed is positioned; A groove having a width and connecting a rear end portion in which the coated optical fiber array portion of the optical fiber array is located in the groove, the front end portion and the rear end portion, and the width of the groove portion of the rear end portion from the width of the groove portion of the front end portion. A basic block having a structure in which the width is changed in a tapered shape so as to gradually change, the connection block having the remaining portion of the optical fiber array from which the coating of the optical fiber array is removed is mounted, and the optical block is mounted on the basic block; An optical fiber fixing block fixing the optical fiber portion from which the coating is removed among the optical fiber arrays mounted on the basic block; And an epoxy fixing part of the optical fiber array located at the connection part of the basic block.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. 1A, 1B and 1C illustrate a plan view, a side view, and a front view of an optical fiber array block according to the present invention. The basic block 120, the optical fibers 100 and 130, and the optical fiber fixing block 110 for mounting the optical fiber are shown in FIG. ) And epoxy 140.

The basic block 120 is a block for mounting an optical fiber array, and comprises a front end portion 102, a rear end portion 106, and a connection portion 104. The front end portion 102 is coupled to an input / output optical waveguide of an optical waveguide device (not shown), has a groove, and optical fibers in which the coating is removed are positioned in the groove. The groove is manufactured so that the optical fiber multiplied by the number of optical fibers to be mounted is 125 μm, which is the clad diameter of the optical fiber from which the coating is removed, so that the optical fiber accurately enters without moving left and right. The rear end 106 is located in the optical fiber coated in one groove. The groove is manufactured to have a width of about the length multiplied by the optical fiber to be mounted to 250㎛ the diameter of the optical fiber including the coating. The connecting portion 104 connects the front end portion 102 and the rear end portion 106 and has a tapered shape so as to gradually change from the width of the groove of the front end portion 102 to the width of the groove of the rear end portion 106. The optical fibers have a structure of varying width, and the coatings are removed. That is, between the front end portion 102 and the rear end portion 106, when the optical fiber is mounted on the basic block, a smooth curved shape is formed at a 125 μm interval of the front end portion 102 at a 250 μm interval of the rear end portion 106. In order to have a structure in which the width changes in a tapered shape so as to gradually change from the width of the groove of the front end portion 102 to the width of the groove of the rear end 106. The length of the connection part 104 is determined by adjusting the length to an appropriate length so that the loss due to bending does not occur in the outermost optical fiber having the largest curvature according to the number of optical fibers to be mounted. In general, as the number of optical fibers to be mounted increases, the length of the tapered region should be longer.

Embodiment a preferred example of making the base block 120 for the optical fiber mount is a method of using a Si crystal substrate, SiO ₂ or Si ₃ N ₄ is SiO ₂ or on a Si substrate formed of a thin film form Si ₃ N ₄ In a strip pattern form, and wet etching in a KOH solution. In this way, the front end and the rear end and the taper area between the front end and the rear end can be manufactured simultaneously. In addition to these methods, such a basic block for mounting optical fibers may be manufactured by mechanical processing, molding, or the like.

The optical fibers 100 and 130 are mounted in a form in which the front end portion 102 and the connection portion 104 of the basic block 120 are removed from the coating, and the rear end portion 106 is used in the form of a coating. Such an optical fiber is effective to use a ribbon optical fiber for mounting and use convenience.

The optical fiber fixing block 110 is manufactured to sufficiently press and fix the optical fiber mounted at the front end portion 102 of the basic block 120. To this end, the shape of the fixing block 110 is preferably configured to take the reverse phase of the basic block 120. One preferred embodiment of the manufacturing of the fixing block 110 is to produce by the wet etching method of Si as in the manufacturing of the basic block 120. In addition to such a method, it is possible to manufacture such a fiber fixing block by a method such as mechanical processing, molding (molding).

The epoxy 140 fixes the optical fiber array from which the coating at the connection portion 104 of the basic block 120 is removed, and the thickness thereof decreases from the front end portion 102 to the rear end portion 106. In addition, the epoxy may fix a predetermined length of the coated optical fiber array located at the rear end 106 as well as the optical fiber array having the coating removed from the connection portion 104 of the basic block 102.

On the other hand, the assembly order of the optical fiber array block is to mount the optical fibers (100, 130) on the base block 120, apply epoxy 140, and the optical fiber fixing block 110 is located in the front end portion 102 of the base block This is achieved by pressing and fixing. After that, the front end of the optical fiber array block is polished so that it can be combined with the input / output optical waveguide on the optical waveguide device at low loss.

The present invention reduces the length of the bending optical waveguide region required to secure the spacing of the input and output waveguides in the optical waveguide device chip by reducing the optical fiber spacing of 250 μm to 1/2 of 125 μm used in the conventional optical fiber array block fabrication. The size of the optical waveguide device can be greatly reduced.

Claims (7)

In the optical fiber array block coupled to the input and output optical waveguide of the optical waveguide device, An optical fiber array, the optical fiber array having a coating removed from the optical fiber by a predetermined length; A front end portion coupled to an input / output optical waveguide of the optical waveguide element, having one groove and having a portion in which the portion of the optical fiber array from which the coating of the optical fiber array has been removed is located; A groove having a width, connecting a rear end portion in which the coated optical fiber array portion of the optical fiber array is located, and the front end portion and the rear end portion, and the width of the groove portion of the rear end portion from the width of the groove portion of the front end portion. A basic block having a structure in which the width thereof is changed in a tapered shape so as to gradually change, and having a connection portion in which the remaining optical fiber array portion from which the coating of the optical fiber array is removed is located, the basic block on which the optical fiber array is mounted; An optical fiber fixing block fixing the optical fiber portion from which the coating is removed among the optical fiber arrays mounted on the basic block; And And an epoxy fixing a portion of the optical fiber array located at the connection portion of the basic block. The method of claim 1, wherein the optical fiber fixing block And an inverted phase of the basic block so as to be suitable for pressing and fixing the optical fiber array mounted on the basic block. According to claim 1, wherein the basic block and the optical fiber fixing block An optical fiber array block produced by at least one of wet etching of silicon crystal substrate, precise mechanical processing, and molding by a mold. According to claim 1, wherein the material of the basic block and the optical fiber fixing block is An optical fiber array block comprising any one of silicon, glass, metal and plastic. The method of claim 1, wherein the basic block is Characterized in that using a silicon crystal substrate, SiO ₂ or Si ₃ N ₄ is SiO ₂ or remove the Si ₃ N ₄ as a strip pattern form on a (100) silicon substrate formed of a thin film form, and prepared by a wet etching in a KOH solution Optical fiber array block. The method of claim 1, wherein the assembly of the optical fiber array block Mounting an optical fiber array on the basic block, applying epoxy, and fixing the optical fiber fixing block by pressing an optical fiber located at a front end of the basic block; And An optical fiber array block comprising the step of grinding the front end surface of the optical fiber array block in order to be able to combine with the input and output optical waveguide on the optical waveguide device chip with low loss. The method of claim 1, wherein the epoxy And a coated optical fiber array fixed to a predetermined length and a coated optical fiber array positioned at a connection portion of the basic block.

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