JPH095563A - Optical fiber coupler manufacturing method and manufacturing apparatus - Google Patents

Abstract

(57) [Summary] [Objective] To provide a manufacturing method and a manufacturing apparatus of an optical fiber coupler having a high yield rate and a high manufacturing efficiency. According to the present invention, in a method of manufacturing an optical fiber coupler in which two polarization maintaining optical fibers are heated, fused, and stretched, an optical fiber having a coating on both sides of a bare optical fiber portion having no coating is provided. The two ends of (2) are gripped by the rotary clamp (3) for each optical fiber and rotated about the center of the cross section of the optical fiber, whereby the polarization main axis directions of the two optical fibers are changed. A method for manufacturing an optical fiber coupler and a device for manufacturing the same, characterized in that they are aligned in parallel. Further, for the bare optical fiber portion (1), a bare fiber clamp (4) other than the above rotary clamp is used to
It is also characterized in that the part is lightly gripped and the parts of the bare optical fiber are closely aligned with each other. Further, in order to facilitate the operation of the bare fiber clamp, the coated portion of the optical fiber between the rotary clamp and the bare fiber clamp is aligned in parallel by using the fiber guide (5) or the coated fiber clamp. There is.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for manufacturing an optical fiber coupler used for optical communication, optical fiber amplifier and the like.

[0002]

2. Description of the Related Art Conventionally, in order to manufacture an optical fiber coupler by heating, fusing, and stretching a polarization maintaining optical fiber, as described in JP-A-5-119228 and JP-A-3-260606, the method is described. Before heating, fusing and stretching
Align the two polarization-maintaining optical fibers parallel to the length direction, and while observing the polarization main-axis direction under a microscope, grasp the bare optical fiber part with a rotating mechanism and rotate it. The main axis directions are the same.

[0003]

However, in the conventional method, the bare optical fiber is strongly gripped and rotated by the rotating mechanism for the purpose of matching the polarization main axis directions of the polarization maintaining optical fiber. The surface of the bare optical fiber may be slightly scratched, resulting in deterioration of the strength of the optical fiber. In addition, it is necessary to align the bare optical fibers parallel to the length direction after heating, melting, and stretching after matching the directions of the principal axes of polarization, but bare optical fibers are aligned parallel to each other because they are slippery between each other. It is difficult to manufacture, and it hinders the improvement of the efficiency and the success rate of the production of the optical fiber coupler.

[0004]

The present invention is a polarization-maintaining optical fiber used in the manufacture of an optical fiber coupler, which is not a bare optical fiber as in the prior art, but is coated and only the portion forming the coupler has no coating. A bare optical fiber is used. Then, both end portions of the coated optical fiber are gripped by a rotary clamp for each optical fiber, and the polarization main axis methods of the optical fibers are aligned in parallel.

Further, regarding the part of the bare optical fiber,
It is characterized in that a bare fiber clamp, which is different from the above rotary clamp, is used to lightly grip the portion and bring the bare optical fiber portions into close contact with each other in parallel, heating, fusing, and stretching. Furthermore, in order to facilitate the operation of the bare fiber clamp, the coated portion of the optical fiber between the rotary clamp and the bare fiber clamp is characterized by being aligned in parallel by using a pair of fiber guides and a coated fiber clamp. .

[0006]

In the present invention, since the rotating clamps are used to grip the coated end portions of the optical fiber and rotate them around the center of the cross section of the optical fiber as an axis, the polarization main axis directions are aligned. Unlike the conventional method, the surface of the bare optical fiber is not damaged and the strength of the optical fiber is not deteriorated.

Regarding the bare optical fiber portion,
A bare fiber clamp other than the above rotary clamp is used to lightly grip the bare optical fiber portion and bring them into close contact with each other in a state where they are aligned parallel to the length direction, and heating, fusing, and stretching operations are performed. Since both ends of the optical fiber are already fixed by the clamp, it is not necessary to firmly hold the optical fiber as in the conventional method, so that the surface of the bare optical fiber is not scratched and the optical fiber is not damaged. The operations of aligning and adhering in parallel, heating, fusing, and stretching become extremely easy and efficient. As a result, the yield rate of the optical fiber coupler is improved and the production efficiency is improved. Further, for the coated portion between the rotating clamp and the bare fiber clamp, either or both of a pair of coated fiber clamps and / or fiber optic guides align the portions in parallel to further facilitate said operation of the bare fiber clamp. can do.

[0008]

Embodiments of the present invention will be described below in detail with reference to the accompanying drawings. In the description of the drawings, the same elements will be denoted by the same reference symbols, without redundant description.

The first embodiment will be described. FIG.
It is the figure which looked at the state where the optical fiber was set to the coupler manufacturing device from above. In FIG. 1, 1 is a bare optical fiber portion from which the protective coating of the optical fiber is removed, 2 is an optical fiber coated portion, 3 is a rotary clamp, 4 is a bare fiber clamp, and 5 is an optical fiber guide.

As for the optical fiber used for manufacturing the optical fiber coupler, first, a polarization-maintaining optical fiber having a coating is used, in which only the portion forming the coupler is stripped of the coating. Alternatively, a bare polarization-maintaining optical fiber may be manufactured first, and a coating may be applied to both end portions not forming a coupler. The polarization-maintaining optical fiber used in the examples is for a wavelength of light of 0.85 μm, and the polarization-maintaining function has a core part of the optical fiber and a stress applying part in the clad lined up in a vertical line. It is formed and applied as described above.

The rotary clamp 3 will be described in detail with reference to FIG. 5. Reference numeral 31 is a fiber holder of the rotary clamp 3, which is the main body of the rotary clamp, and 32 is the fiber holder 3.
1 is a chuck portion, 33 is a rotation mechanism portion, and 34 is a base for holding the rotation mechanism portion. The coated portion 2 of the optical fiber is inserted into the fiber holder 31, and is gripped and fixed by the chuck portion 32 of the fiber holder. The central axis of rotation of the rotation mechanism 33 coincides with the center of the cross section of the fiber holder 31 and the coated portion 2 of the optical fiber.
By rotating 3 with a fingertip, the coated portion 2 of the optical fiber can be rotated and the polarization main axis directions can be aligned accurately.

The rotary clamp 3 may be the one shown in FIG. In FIG. 6, 42 is a fiber clamp, 41 is a hinge part of 42, 43 is a rotation mechanism part, 44
Is an arm connecting the fiber clamp 42 and the rotation mechanism portion 43, 45 is a base for holding the rotation mechanism portion 43, and 46 is an opening for passing an optical fiber of the rotation mechanism portion 43. The coated portion 2 of the optical fiber is gripped and fixed by the fiber clamp 42 at a position where the center of the cross section thereof coincides with the rotation center of the rotation mechanism portion 43. Therefore, by rotating the rotation mechanism portion 43 with a fingertip, the coated portion 2 of the optical fiber can be smoothly rotated without swinging the axis of rotation.

The rotary clamp 3 other than the one shown in FIGS. 5 and 6 holds the coated portion 2 of the optical fiber, and
Any optical fiber may be used as long as it can be rotated without the axis swinging with the center of the cross section of the optical fiber as the axis of rotation.

The bare fiber clamp 4 is intended for aligning and closely contacting the optical fibers in parallel, and two pieces of suitable linear grooves having the same diameter as the optical fiber are provided in the portion in contact with the bare optical fiber. The above object is achieved by lightly gripping the bare optical fiber portion from above and below using a stainless steel plate and a suitable spring mechanism for connecting the stainless steel plate. However, the structure is not limited to this, and another structure may be used as long as the bare optical fibers can be aligned in parallel. The material is preferably made of metal, plastic, or the like having a hardness lower than that of glass so as not to damage the optical fiber. By the way, since the bare fiber clamp 4 lightly grips the optical fiber, even when the optical fiber is gripped by this clamp, the polarization direction of the polarization main axis can be aligned by the rotary clamp 3.

The fiber guide 5 is composed of four pins standing at an intermediate position between the rotary clamp 3 and the bare fiber clamp 4, and an appropriate pressure is applied inward from both sides of the two optical fibers by spring stress. It has become.

In manufacturing the optical fiber coupler, first, two optical fibers are set in the rotary clamp 3 with the bare fiber clamp 4 and the optical fiber guide 5 being opened.

Next, the polarization main axis direction is adjusted, and this state is shown in FIG. The bare optical fiber portion 1 is dipped in a matching oil whose refractive index matches that of the glass forming the bare optical fiber portion, and in this state, the illumination 106 illuminates the bare optical fiber portion 1 with light. The transmitted light is the microscope 1
While observing at 05, the polarization main axis direction is adjusted. The polarization main axis direction of the optical fiber is the core 102a and the clad 102b.
The stress applying portions 103 and 104 are arranged in a line in the vertical direction, and the rotation clamp 3 rotates and adjusts the optical fibers so that the directions are aligned in parallel.

After the polarization main axis direction is adjusted, the two optical fibers are aligned in parallel by the optical fiber guide 5.

Next, a pair of bare fiber clamps 4 are set at both ends of the two bare optical fiber portions 1 and a proper tension is applied in the length direction so as to be in close contact with each other in parallel with the length direction. Fix with.

In this state, the bare optical fiber portion 1 is heated and fused to fuse the two optical fibers together. Furthermore, while heating the bare optical fiber part 1,
By expanding the distance between the optical fibers of the left and right rotary clamps 3, the portions of the optical fibers closely contacted in parallel with each other in the length direction are stretched to complete the optical fiber coupler.

The optical characteristics of the manufactured optical fiber coupler are as follows.
Since the polarization-maintaining optical fiber for the wavelength of 0.85 μm was used, the evaluation was performed by using the light source of the LED having the center wavelength of 0.85 μm. As a result, the excess loss is 0.12 dB, the branching ratio is 50.4%, the crosstalk on the main line side is −28 dB, and the crosstalk on the branch line side is −27 dB. The talk can be made extremely low.

Here, the excess loss (EL) is the ratio of the power P0 of the light incident on the optical fiber coupler to the power (P1 + P2) of the light emitted from the optical fiber coupler, and is expressed by the equation (1). Is defined by However, P1 is the power of light emitted from the inner main line side of the power of the light emitted from the optical fiber coupler, and P2 is the power of light emitted from the branch line side. EL = 10 · log ₁₀ ((P1 + P2) / P0) (dB) (1) The branching ratio (SR) is the power of the light emitted from the branch line with respect to the power (P1 + P2) of the light emitted from the optical fiber coupler. It is the ratio of -P2 and is defined by equation (2). SR = P2 / (P1 + P2) × 100 (%) (2) Crosstalk (CT) is the power of light with the same polarization as that of the incident light, out of the light emitted from the optical fiber coupler. It is an amount obtained by multiplying the logarithm of the power ratio of polarized light in the direction at right angles by 10 and is defined by the equation (3). CT = 10 × Log ₁₀ (Py / Px) (dB) (3) where Px is the power of the X-polarized light in the outgoing light when the X-polarized light is incident on the optical fiber coupler, P
y is the power of the Y polarized light.

Regarding the strength characteristics of the manufactured optical fiber coupler, the bare optical fiber portion does not break even when a load of 1 kg is applied to the coated fiber portion at the end of the optical fiber coupler. This is because when the optical fiber coupler is manufactured, a method of gripping the coated portion of the optical fiber with the rotary clamp 3 to align the polarization main axis directions is adopted, so that it is not necessary to strongly grip the bare optical fiber portion 1. This is because the surface is not damaged and the strength of the optical fiber is not deteriorated. By the way, a bare fiber clamp 4 different from the rotary clamp 3 is used to grip the bare optical fiber portions and align them in parallel to the length direction. Since it is already fixed, it is not necessary to firmly grip the bare optical fiber portion as in the conventional method, and only light pressure is applied.
Does not scratch the surface of the bare optical fiber part.

The second embodiment will be described. In FIG.
The figure which looked at the state which set two optical fibers to the manufacturing apparatus of the optical fiber coupler by a present Example from above is shown. In FIG. 3, reference numeral 6 indicates a coating clamp. The coating clamp 6 is a clamp that grips the coated portions on both sides of the bare optical fiber portion from above and below to align the optical fibers in parallel, and it is intended to make the operation of the bare fiber clamp 4 easier. . The structure uses two stainless steel plates having a plurality of shallow linear grooves having the same diameter as the coating portion 2 of the optical fiber and an appropriate spring mechanism for connecting the two stainless steel plates. However, the structure is not limited to this, and another structure may be used as long as the optical fibers can be aligned in parallel.

Further, FIG. 4 shows a side view of the manufacturing apparatus of the optical fiber coupler shown in FIG. Reference numeral 7 in FIG. 4 denotes a coated fiber clamp moving mechanism, which is a bare optical fiber 1
While moving the moving mechanism 7 in the direction in which the distance between them increases in the heating, fusing, and stretching steps of
A part of the bare optical fiber 1 is drawn.

When manufacturing the optical fiber coupler, two fibers are set in the rotary clamp 3 with the bare fiber clamp 4, the coating clamp 6 and the optical fiber guide 5 opened, and then the bare optical fiber is removed. The portion 1 is dipped in a matching oil having a refractive index matching that of the glass constituting the bare optical fiber portion. In this state, as shown in FIG. 2, the bare optical fiber portion 1 is illuminated by the illumination 106 and the transmitted light is observed by the microscope 105. The polarization main axis direction of each optical fiber is adjusted and aligned by the rotary clamp 3 so that the stress applying portions 103 and 104 in the core 102a and the clad 102b are aligned in a vertical line. After the polarization main axis direction is adjusted, the coated portion 2 of the optical fiber is set in the optical fiber guide 5 and the coated fiber clamp 6 to keep the two optical fibers in a parallel state. After that, the bare optical fiber 1 is set in the bare fiber clamp 4 so that the bare optical fiber portion 1 of the two optical fibers is closely attached in parallel in the longitudinal direction and fixed. In this state, the bare optical fiber portion 1 is heated to fuse and fuse the two optical fibers together. Next, while further heating the bare optical fiber portion 1, the distance between the pair of coated fiber clamps 6 is widened by the coated fiber clamp moving mechanism 7 to stretch the integrated bare optical fiber portion, Fabricate an optical fiber coupler.

The optical characteristics of the manufactured optical fiber coupler are as follows.
Evaluation was performed using an LED having a center wavelength of 0.85 μm. As a result, the excess loss is 0.10 dB, the branching ratio is 49.2%, the crosstalk on the main line side is -27 dB, and the crosstalk on the branch line side is -25 dB, which is extremely low by accurately matching the polarization main axis directions by the rotation clamp. Can be crosstalk.

Further, even if both ends of the optical fiber coupler are pulled by a load of 1 kg, the bare optical fiber portion does not break, and in this case as well, the surface of the bare optical fiber portion is not damaged and the optical fiber is not damaged. No deterioration of strength has occurred.

[0029]

As described above, according to the present invention, when the polarization main axis direction of the polarization maintaining optical fiber is aligned parallel to each other, the coated portion of the optical fiber is gripped and rotated. Since it is not necessary to strongly grip the portion of, the surface thereof is not damaged and the strength of the optical fiber is not deteriorated. Furthermore, by using a bare fiber clamp, an optical fiber guide, and a coated fiber clamp in addition to the rotary clamp, the operation of aligning and closely adhering the bare optical fiber portions in parallel and fusing and stretching is facilitated. Therefore, according to the present invention, it is possible to improve the yield rate and the manufacturing efficiency in manufacturing the polarization maintaining optical fiber coupler.

[0030]

[Brief description of drawings]

FIG. 1 is a top view of a state in which two optical fibers are set in an optical fiber coupler manufacturing apparatus in a first embodiment.

FIG. 2 is a diagram showing a method for aligning the polarization main axis directions of an optical fiber.

FIG. 3 is a top view of a state in which two optical fibers are set in an optical fiber coupler manufacturing apparatus in the second embodiment.

FIG. 4 is a side view showing a state in which two optical fibers are set in the optical fiber coupler manufacturing apparatus of FIG.

FIG. 5 is a diagram showing a first example of a rotary clamp.

FIG. 6 is a diagram showing a second example of a rotary clamp.

[Explanation of symbols]

 1: Bare optical fiber portion with coating removed 2: Optical fiber portion with coating 3: Rotating clamp 4: Bare fiber clamp 5: Optical fiber guide 6: Coating clamp 102a: Core portion of optical fiber 102b: Optical fiber Clad part 103, 104: stress applying part 105: microscope 106: illumination

Claims (7)

[Claims] 1. A method of manufacturing an optical fiber coupler in which two polarization maintaining optical fibers are heated, fused and stretched,
The coated optical fiber portions on both sides of the bare optical fiber portion with the coating removed are gripped by rotating clamps for each optical fiber and the optical fibers are rotated, whereby the two optical fibers are biased. Method for manufacturing optical fiber coupler characterized by aligning wave principal axis directions in parallel 2. The both ends of the bare optical fiber portion are clamped by bare fiber clamps, and the bare optical fiber portions are brought into contact with each other in parallel in the longitudinal direction to heat, fuse,
Stretching is performed, The manufacturing method of the optical fiber coupler of Claim 1 characterized by the above-mentioned. 3. The portion of the coated optical fiber between the rotary clamp and the bare fiber clamp is aligned parallel to the length direction using an optical fiber guide. Method for manufacturing the described optical fiber coupler 4. The coated optical fiber portion between the rotary clamp and the bare fiber clamp is gripped by the coated fiber clamp and aligned in parallel to the length direction. 3. A method for manufacturing an optical fiber coupler according to any one of 3 5. The bare optical fiber portion of the two optical fibers is stretched by heating the bare optical fiber portion of the two optical fibers while widening the distance between the rotary clamps. 4. The method for manufacturing an optical fiber coupler according to claim 1. 6. The portion of the bare optical fiber is stretched by increasing the distance between the coated fiber clamps while heating the portion of the bare optical fiber of the two optical fibers. The method for manufacturing an optical fiber coupler according to claim 4. 7. An optical fiber coupler manufacturing apparatus used in any one of the optical fiber coupler manufacturing methods according to claim 1. Description: