JPH06289248A - Auxiliary means for fixing optical fiber for optical element and fixing method - Google Patents

Abstract

PURPOSE:To provide the auxiliary means for easily adhering and fixing the light signal input and output ends of an optical element and optical fibers and the fixing method. CONSTITUTION:The end faces of the optical fibers 9 inserted into cut out spaces 5, 6 are adjusted in optical axis and joined to the light signal input and output end faces 8 of the optical element by using the auxiliary means 1 which consists of a plane part 2 placed and fixed onto the ends of the optical element and the downward extending parts 4 connected at one end thereof and is formed with >=1 pieces of cut out spaces 5, 6 for receiving the optical fibers 9 to these parts. Adhesives are injected into these cut out spaces 5, 6 and are cured to fix these end faces.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical fiber fixing aid for fixing an optical fiber, particularly a large number of optical fibers in parallel, to an optical signal input / output end of an optical element.
The present invention relates to an optical fiber fixing method, and is useful for connecting an optical fiber to an optical waveguide device such as an optical modulator or a multi-branching waveguide device such as an optical switch.

[0002]

2. Description of the Related Art For example, when connecting and fixing an optical fiber to the end face of a waveguide type optical element, after adjusting and aligning the optical axes of the optical fiber and the optical waveguide, for example, an ultraviolet curing adhesive is applied to the connecting portion. There is a known method of bonding. In general,
Since the materials of the optical element (ferroelectric crystal such as LiNbO ₃ ) and the optical fiber (SiO ₂ ) are greatly different, it is difficult to directly fuse the two. Therefore, a fixing method using an adhesive is adopted. ing.

However, the diameter of the bare optical fiber is as small as 0.125 mm, and when the optical fiber is point-bonded and fixed to the end face of the optical element with only this minute cross-sectional area, the adhesive strength is very small. Therefore, it becomes extremely easy to peel off. For example, when 10 naked optical fibers are adhesively fixed to the end surface of the LiNbO ₃ chip using an ultraviolet curable adhesive (N57, made by NTT), the tensile strength of this joint is 5.1 gf on average and a standard deviation. 1.8gf
It was about.

In order to solve the above problems, for example,
A method is known in which a bare optical fiber is inserted into a capillary (a glass cylinder having an inner diameter of about 0.128 mm), and the optical fiber is bonded to the end surface of the optical element together with the capillary to widen the bonding area with the end surface of the optical element. For example, when an optical fiber is passed through a capillary having an outer diameter of 1 mm as an adhesion aid and adhered using an adhesive (N57, made by NTT), the adhesive strength is 823 gf on average and 188 gf standard deviation.
Improve to. Therefore, when the optical fiber is adhesively fixed to the end face of the optical element, it is effective to use the auxiliary tool to improve the adhesive fixation strength.

On the other hand, when a plurality of optical fibers are juxtaposed and fixed to the end face of an element like an optical switch element, in addition to the above-mentioned role of assisting the adhesive strength, a plurality of optical fibers are simultaneously aligned on the end face of the element. Then, it becomes necessary to bond and fix them, and an optical fiber holder called a fiber array is used.

As the fiber array, generally, a V-shaped groove for arranging optical fibers on a flat plate is formed at a predetermined interval. As a flat plate for forming the V-groove, for example, a crystalline silicon plate is used, and a high photolithographic technique is applied by an anisotropic etching method utilizing that the wet etching rate strongly depends on the crystal plane of silicon. A V-groove array with dimensional accuracy has been produced (for example, "low stroke polarization independent 1.55 μm 1 × 8 Ti: LiNb
O ₃ Optical Waveguide Switch ”, Nakaya, Funaki, Toyohara, Kawashima, Izeki, IEICE Technical Report, OQE92-4
1). Further, a glass plate, a ceramic plate, or the like in which V grooves are precision machined by machining is also used.

The conventional optical fiber bonding and fixing aid as described above is a system in which a capillary or a fiber array body containing an optical fiber is bonded and fixed on the end surface of the optical element, that is, on the same surface as the surface to which the optical fiber is connected. Is.

[0008]

When the above-mentioned conventional fixing aid is used, particularly when a plurality of optical fibers are adhered, the following practical problems occur.

Since the plurality of optical fibers are preliminarily integrated in parallel on the fiber array, the optical axes of the corresponding optical waveguides on the optical element are simultaneously adjusted to the optimum state for all the optical fibers. Is difficult.

Further, in order to adjust the optical axes of a plurality of optical fibers at the same time, the parallel spacing of the optical waveguides on the optical element,
Not only are the intervals of the grooves in the fiber array jig that accommodate the optical fibers match exactly on the submicron order, but the cores of the fiber end faces housed in the grooves are sub-shaped both horizontally and vertically. Must be aligned on the order of microns.

When the number of optical fibers to be aligned is small, it is possible to satisfy the strict condition as described above, but it becomes technically difficult as the number of optical fibers increases,
The manufacturing yield also deteriorates. Even if a precise fiber array could be produced, the state of the waveguide entrance / exit end changes due to the polishing state of the end face of the optical element, etc., and the optical coupling axis with the ideal fiber is delicately changed from the design. There is a possibility of deviation, and optimal optical coupling cannot be performed, that is, the yield is reduced.

Further, when the number of optical fibers is increased and the size of the fiber array is increased, in order to prevent the axis misalignment due to a change in ambient temperature, the coefficient of thermal expansion of the block holding the optical fiber and that of the optical element are matched. Is preferred. For this purpose, it is ideal that the block is made of the same material as the optical element, but the material used for the optical element, for example, LiNbO ₃ single crystal, is not always suitable for the ultra-precision groove processing as described above. Not a material. In terms of precision processing, an alumina-based material, glass, or the like, which is free from machinability or has little deformation due to processing heat, is suitable.

An object of the present invention is to easily achieve the severe machining accuracy and axial adjustment accuracy required in such a conventional type optical fiber fixing aid and a fixing method using the same, and An object of the present invention is to provide an optical fiber fixing auxiliary tool for an optical element and a fixing method which are simple and easy to process.

[0014]

An optical fiber fixing aid for an optical element according to the present invention has an optical fiber end face on the optical signal input / output end face of an optical device having one or more optical signal input / output ends. An auxiliary tool for connecting and fixing this, which is a flat portion placed on the end portion of the optical element, and extends downward from the end portion of the flat portion to the outside of the optical element. And a downward extending portion that is present, and the flat surface portion is formed with one or more flat cutout spaces corresponding to the optical signal input / output end and for receiving an optical fiber connected thereto. In the downward extension part, one or more downward extension cutout spaces continuous with each of the planar cutout spaces, extended downward, and for receiving the optical fiber are formed. Is.

Further, a method for fixing an optical fiber to an optical element according to the present invention is the optical fiber fixing auxiliary tool for an optical element as described above, wherein an end portion of the optical element has a planar cutout space,
Arranged and fixed so as to be located on the optical signal input / output end,
An optical fiber is inserted into the flat cutout space through the extension cutout space, the end face of the optical fiber is arranged so as to face the optical signal input / output end face of the optical element, and an adhesive is provided. It is characterized in that the optical fiber is fixed to the auxiliary tool and the optical element by injecting into the planar cutout space and the extended cutout space and solidifying the same.

In the present invention, even when a plurality of optical fibers are bonded and fixed, one optical fiber is attached to each optical signal input / output end face of the optical element (optical waveguide), as in the case of one optical fiber. It becomes possible to adjust the optical axis in order and adhere and fix.

[0017]

FIG. 1 is a perspective view of an example of an auxiliary tool of the present invention used for adhesively fixing an optical fiber to an optical signal input / output end of an optical element. FIG. 2 shows this auxiliary tool. 4 is a plan view of the tool, FIG. 3 is a side view of the auxiliary tool, and FIG.
[Fig. 4] is a front view of this auxiliary tool.

1, 2, 3 and 4, an optical fiber fixing aid 1 has a flat surface portion 2 and a downwardly extending portion 4 extending downward from an end portion 3 of the flat surface portion 2. Is. One or more flat cutout spaces 5 are formed in the flat surface portion 2 of the auxiliary tool 1, and the downward extension portion 4 is continuous with the flat surface cutout space 5 and extends downward 1 6 or more downwardly extending cutout spaces 6
Are formed.

As shown in FIGS. 1, 2, 3, and 4, the flat part 2 of the auxiliary tool 1 is placed and fixed on the end of the optical element 7 having the optical signal input / output end. The downwardly extending portion 4 is arranged outside the end of the optical element 7 so as to extend downwardly. At this time, the auxiliary tool 1 is arranged such that the planar cutout space 5 is located on the terminal portion 8a (FIG. 4) of the optical signal input / output end portion (eg, optical waveguide end portion) 8 of the optical element end portion. It

At this time, the plane cut-out space 5 and the optical signal input / output end terminal 8a may extend in parallel, or may have a desired inclination angle. When both are inclined, the optical fiber is bonded and fixed to the optical signal input / output end at this angle. Such an oblique incidence method can reduce the coupling loss due to light reflection at the interface between the optical fiber end face and the optical signal input / output end face (optical waveguide end face).

The end face of the optical fiber 9 inserted into the flat cut-out space 5 is opposed to the end face of the optical signal input / output terminal 8a exposed in the flat cut-out space 5 through the cut-out cut-out space 6 extending downward. Then, the relative positional relationship between the two is adjusted so that the optical axes coincide with each other. The above operation is performed for each of the plurality of optical fibers.

The cutout spaces 5 and 6 of the flat surface portion 2 and the downwardly extending portion 4 have a width satisfying D + S with respect to the outer diameter (D) of the optical fiber 9 inserted therein, for example, the optical fiber 9 When the outer diameter (D) is 0.125 mm, S
= 2 μm to 0.2 mm is preferable. That is,
The cutout spaces 5 and 6 have the optical fiber 9 inserted therein.
Since there is a clearance of width S on both sides, the optical axis in the horizontal direction between the end face of the optical fiber 9 and the optical signal input / output end face of the optical element 7 can be easily adjusted.

The cutout space 6 extending downward is
As shown in FIG. 3, clearances (for example, 2 μm to 0.2 mm) are provided above and below the optical fiber 9, so that the end face of the optical fiber 9 and the optical signal input / output end face of the optical element 7 are It is possible to easily adjust the optical axis in the vertical direction.

In the auxiliary tool of the present invention, the flat surface portion 2 thereof
Is placed on the end of the optical element 7, and the planar cutout space 5 extends over the optical signal input / output end for a considerable length, so that the optical fiber end face and the optical signal input / output end face are The bonding can be performed not only on the terminal surface 10 of the optical element 7 as shown in FIG. 4 but also on the inner side thereof.

As described above, when the optical axis adjustment between the end face of the optical fiber 9 and the optical signal input / output end face of the optical element 7 is completed, the flat cutout space 5 and the downward cutout cutout space 6 are bonded. The optical fiber 9 is injected with the agent and solidified.
Is fixed to the auxiliary tool 1 and the optical element 7.

As described above, the optical fiber fixing aid of the present invention is used for connecting the optical signal input / output end of the optical element and the optical fiber. Generally, the optical element is a waveguide. The auxiliary tool of the present invention is particularly effective in the case of a type optical device and the optical signal input / output end is the optical waveguide end.

In the assisting tool of the present invention, the number of flat cutout spaces and the downward cutout cutout spaces continuous therewith are formed so as to match the number of optical signal input / output ends of the optical element.

As described above, the end face of the optical fiber,
As one method of reducing the coupling loss due to the light reflection at the interface with the optical signal input / output end face, when the “oblique incidence” method is adopted, the plane cutout space is a predetermined distance from the optical signal input / output end portion. Is formed with an inclination angle of.

Further, as described above, the width of the cutout space is set so as to satisfy D + S with respect to the outer diameter D of the optical fiber. For example, when D = 0.125 mm, S = 2 μ.
About m to 0.2 mm is sufficient. Since the diameter of the optical fiber and the width of the optical waveguide are on the order of μm and have high precision and reproducibility, the value of S is sufficient on the order of μm. The value of S is preferably small in order to accurately adjust the bonding position between the auxiliary tool and the optical fiber.

The material constituting the auxiliary tool of the present invention is not particularly limited, and is made of, for example, quartz glass, or the same material as the substrate material of the optical element, such as LiN.
It may be bO ₃ . It is preferable that the material of the auxiliary tool and the material of the substrate of the optical element are the same from the viewpoint of matching the mechanical and thermal characteristics of both.

In the auxiliary tool of the present invention, the cutout space can be formed by machining with a cutting blade, but in the optical fiber fixing method using the auxiliary tool of the present invention, the optical axis of the optical fiber can be easily adjusted sequentially. Therefore, the machining accuracy of the cutout space does not require the submicron ultrahigh precision of the conventional auxiliary tool. When a thin blade is used for the cutting process, the width of the cutout space formed tends to be wider than the thickness of the blade by about 3 μm due to the waviness of the blade.

[0032]

EXAMPLE An optical fiber fixing aid having four cutout spaces as shown in FIG. 1 was produced. The material of the auxiliary tool was LiNbO ₃ , which was the same as the substrate material of the optical element to which the optical fiber was to be joined. The auxiliary material was composed of a flat plate portion having a thickness of 0.3 mm and a downward extending portion having a thickness of 0.5 mm, and had an L-shaped cross-sectional shape as shown in FIG. This L-shaped material has a thickness of 0.125
A linear cutting space was formed using a mm slicing blade. There was a blade deviation of about 3 μm, so the width of the linear cutout space obtained was 0.128 mm.

The flat surface portion of the auxiliary tool manufactured as described above was arranged on the end portion of the optical waveguide type optical element so that the cutout space of the auxiliary tool was located above the optical waveguide. The coating at the end of the optical fiber is removed to expose a bare optical fiber having an outer diameter of 0.125 mm, and the bare optical fiber is inserted into the cutout space to adjust the optical axis between the end face and the end face of the optical waveguide. I went and matched both optical axes. Next, an ultraviolet curable adhesive is injected into the cutout space, and this is irradiated with ultraviolet rays to cure the adhesive. Bare optical fiber end face,
The end face of the optical waveguide was adhesively fixed at a predetermined position, and the auxiliary tool was adhesively fixed to the optical element.

[0034]

EFFECTS OF THE INVENTION The assisting tool of the present invention does not require ultra-high precision in dimension as compared with the conventional assisting tool, but by using such an assisting tool of the present invention, One or more, especially a plurality of optical fibers can be adhered and fixed to the optical input / output end of the optical element by precisely adjusting the optical axis, and its practical utility is extremely high.

[Brief description of drawings]

FIG. 1 is a perspective explanatory view showing a configuration of an example of an optical fiber fixing auxiliary tool for an optical element of the present invention and a situation in which an optical fiber is adhesively fixed to an optical signal input / output end of an optical element using the same.

FIG. 2 is an explanatory plan view of the auxiliary tool of FIG.

FIG. 3 is a front explanatory view of the auxiliary tool of FIG. 1.

FIG. 4 is a side view for explaining the auxiliary tool of FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Auxiliary tool 2 ... Plane part 3 ... Plane part end part 4 ... Downward extending part 5 ... Planar cutout space 6 ... Downward extending cutout space 7 ... Optical element 8 ... Optical signal input / output end 8a ... Optical signal input / output End terminal part 9 ... Optical fiber 10 ... End surface of optical element

 ─────────────────────────────────────────────────── ─── Continued Front Page (72) Inventor Hirotoshi Nagata 585 Tomimachi, Funabashi, Chiba Sumitomo Cement Co., Ltd. Central Research Laboratory

Claims (2)

[Claims] 1. An auxiliary tool for connecting an optical fiber end face to the optical signal input / output end face of an optical device having one or more optical signal input / output ends, and fixing the optical fiber end face, the optical device A flat portion to be mounted on an end portion of the optical element, and from the end portion of the flat portion to the outside of the optical element, a downward extending portion extending downward is provided, and the flat portion includes the light One or more planar cutout spaces are formed corresponding to the signal input / output ends and for receiving the optical fibers connected to the signal input / output ends. The downwardly extending portion is continuous with each of the planar cutout spaces, An optical fiber fixing aid for an optical element, which extends downward and has at least one downwardly extending cutout space for receiving the optical fiber. 2. An optical fiber fixing aid for an optical element according to claim 1, which is arranged and fixed to an end portion of the optical element such that a planar cutout space is located above the optical signal input / output end portion. , An optical fiber is inserted into the planar cutout space through the extending cutout space, the end face of the optical fiber is arranged so as to face the optical signal input / output end face of the optical element, and an adhesive is applied. , Solidified by pouring into the flat cutout space and the extended cutout space,
A method of fixing an optical fiber to an optical element, comprising fixing the optical fiber to the auxiliary tool and the optical element.