JPH0882721A - Heater for fusion spliced part of multiple optical fiber cable - Google Patents

Abstract

PURPOSE: To lessen the connection loss of a juncture when different multiple optical fiber cables are fusion spliced to each other by forming the opening of a microtorch to a flat shape and providing its flat opening with constricted parts. CONSTITUTION: The microtorch 2 constituting the important part of this heater 1 has the flat opening 3 and is provided with the constricted part 4 at three points at equal intervals in the major axis direction of this flat opening. In such a case, the size of the flat opening 3 of the microtorch 2 is determined in compliance with the structural size of optical fiber ribbon cables 12, l3, but since there is a need for simultaneously heating the entire part of the juncture after fusing, the flat type opening 3 is formed to the same major axis and minor axis sizes as the major axis and minor axis sizes of the optical fiber ribbon cables 12, 13 or to the sizes slightly larger than these sizes. The constricted parts 4 of the flat type opening have purposes of uniformizing the temp. distribution gaseous flame tips 5 in the major axis direction of the flat type opening 3 and, therefore, the sizes, number of installation, installation points, etc., of the constricted parts 4 are determined from the flow rates of gases, the sectional sizes of the optical fiber ribbon cables 12, 13, etc.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-core fiber suitable for reducing the splice loss between core splicing parts in which multi-fiber optical fiber tape cables having different mode field shapes and dimensions are fusion-spliced to each other without variation. The present invention relates to a fusion splicing part heating device for an optical fiber tape cable.

[0002]

2. Description of the Related Art For example, in an optical fiber cable connected to an optical device using a semiconductor optical waveguide such as an optical switch or a star coupler, a plurality of optical fibers are formed in a flat shape in order to achieve high density mounting of the optical device. A multi-fiber optical fiber tape cable is used which is formed into an array. Further, generally, the spot size of the semiconductor optical waveguide is about a fraction of the size of the mode field diameter of a general single-mode optical fiber, and its shape is elliptical. As much as possible, the optical fiber to be connected to is used with a mode field diameter that matches the spot size shape and size of the optical waveguide in order to reduce the connection loss. Such an optical device is used by being connected to a single mode optical fiber tape cable having a normal mode field diameter via a multi-core optical fiber tape cable connected to the optical device.

However, when such optical fiber tape cables having different mode field diameters and mode field shapes are fusion-spliced to each other, the loss at the connection portion due to the difference in mode field diameter and mode field shape is a big problem. Becomes In order to reduce the splice loss at the fusion spliced portion, it is necessary to expand the mode field diameter of the connecting optical fiber tape cable so that the mode field diameter of the splicing optical fiber tape cable substantially matches the mode field diameter of the single mode optical fiber tape cable. As such means,
A high refractive index (high Δ) optical fiber with a large amount of Ge or other dopant added to the core is used as a connecting optical fiber tape cable, and the connecting optical fiber tape cable and the single mode optical fiber tape cable are fused together. After splicing and splicing, each fusion spliced part is reheated to increase the mode field diameter by thermally diffusing the dopant of the splicing optical fiber tape cable core, which is almost the same as the mode field diameter of the single mode optical fiber tape cable. A means for heating the fusion spliced part is provided.

As a heating means for the fusion splicing portion between the optical fiber tape cables, as shown in FIG. 5, the same splicing electrode 51, 51 as in the fusion splicing is used, and the fusion splicing portion 181 is used.
6 and a micro torch 61 having a small-diameter cylindrical tip opening 62 as shown in FIG.
3 is used to heat the fusion splicing portion 181. 5 and 6, 121 and 131 are optical fiber tape cables, 14 and 15 are optical fiber strands, and 16 and 17 are resin coatings.

[0005]

However, in the former discharge heating means, since the heating area by discharge is narrow, sufficient energy is required to thermally diffuse the dopant in the connecting optical fiber tape cable core. Is difficult to give, and a sufficient heat diffusion effect cannot be obtained even if the discharge is repeated a considerable number of times. For example, even when the discharge heating is performed 30 times, the splice loss of the fusion splicing portion is improved from about 2.1 dB at the time of fusion to about 0.92 dB. It has been insufficient as a heating means for reducing the splice loss of the fusion spliced portions.

Further, in the heating means using the latter micro torch having a small-diameter cylindrical tip, since the flame tip of the micro torch is a tip of a brush and has a narrow heating range, each fiber of the optical tape cable is In order to heat the fusion spliced portion, it was necessary to move the tip of the writing flame along each fiber fusion spliced portion. It is extremely difficult to uniformly heat each fiber fusion splicing part while moving the flame, and therefore the thermal diffusion of the dopant of the connecting optical fiber tape cable core in each fiber fusion splicing part,
That is, it was easy to cause variations in the expansion of the mode field diameter of the connecting optical fiber tape cable. According to an experimental example using this heating means, in each fiber fusion splicing part, splice loss is greatly improved from 2.1 dB at the time of fusion splicing to 0.1 dB. There was a large variation in the reduction of the splice loss between the fusion spliced parts, and a maximum difference of 1.0 dB in loss was generated between the spliced parts. Therefore,
This heating means also has a problem as a heating means for reducing the splice loss of the fusion spliced joint between the optical fiber tape cables.

The present invention has been made in order to solve the above-mentioned problems of the prior art, and a multi-fiber optical fiber tape cable having different mode field shapes and dimensions from each other is fusion-bonded to each other. It is an object of the present invention to provide a heating device for a multi-core optical fiber tape cable splice part which is effective in reducing splice loss.

[0008]

A multicore optical fiber tape cable fusion splicing section heating device of the present invention that achieves the above object has a flat opening having a tip end opening of a microtorch substantially the same as the outer dimension of the optical fiber tape cable. The flat opening is formed with at least one constricted portion constricted in the minor axis direction of the opening. When the flat opening is provided with one constricted portion, it is provided substantially at the center of the flat opening of the microtorch. When a plurality of constricted portions are provided, they are arranged at substantially equal intervals in the major axis direction of the flat opening of the microtorch.

[0009]

In the multi-fiber optical fiber tape cable fusion splicing portion heating device of the present invention having the above-described structure, the microtorch tip opening is formed into a flat shape having substantially the same outer dimensions as the optical fiber tape cable, and the flat opening portion is formed. Is provided with at least one constricted portion constricted in the minor axis direction of the opening. If the micro torch tip opening is simply formed in a flat shape, the gas flow rate will be the largest at the center of the flat opening and will decrease at both ends of the flat opening, and the temperature distribution of the flame at the tip of the micro torch will be mountainous, resulting in a desirable temperature distribution. I won't. However, by providing a constricted part in the flat opening, the gas flow rate is reduced in the constricted part and averaged in the openings other than the constricted part.As a result, the temperature distribution of the flame at the tip of the micro torch is as a whole in the longitudinal direction of the flat opening. Form a flat distribution. Therefore, each fiber fusion splicing part formed in a flat shape of the multi-fiber optical fiber tape cable can be uniformly heated at the same required temperature at the same time, and the splicing loss of each fiber fusion splicing part varies. Significantly reduced without occurring.

[0010]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is an explanatory view showing one embodiment of a fusion splicing part heating device for a multi-fiber optical fiber tape cable according to the present invention. Reference numeral 1 is a heating device, which is a main part of the micro torch 2
Has a flat-shaped opening 3 and a constricted portion 4 in the long-axis direction of the flat-shaped opening.
Are provided at three locations at equal intervals. The size of the flat opening 3 of the microtorch 2 is determined according to the structural size of the optical fiber tape cable, but since the entire fusion splicing portion needs to be heated at the same time, the long diameter and the short diameter of the flat opening 3 are equal to the optical length. The fiber tape cable is manufactured to have a dimension substantially the same as or slightly larger than the major and minor dimensions of the fiber tape cable. Further, since the flat-shaped opening constricted portion 4 has the purpose of making the temperature distribution of the tip 5 of the gas flame uniform in the major axis direction of the flat-shaped opening 3, the size and the number of the constricted portions 4, the installation location, etc. It is determined in consideration of the cross-sectional dimensions of the optical fiber tape cable. For example, FIG. 2B shows an embodiment of the opening cross section 31 of the micro torch used for heating the fusion splicing part of the four-core optical fiber tape cable 131, and 4 is a constricted part. FIG. 3A shows a cross-sectional view of the four-core optical fiber tape cable 131, wherein 15 is an optical fiber, 15a is a core, 15b is a clad layer, and 17 is a resin coating. Further, FIG. 3B shows an embodiment of the opening cross section 3 of the micro torch used for heating the fusion splicing portion of the 8-fiber optical fiber tape cable 13, and 4 is a constricted portion. FIG. 3 (a)
Shows a sectional view of the 8-fiber optical fiber cable 13,
Reference numeral 15 is an optical fiber, 15a is a core, 15b is a clad layer, and 17 is a resin coating.

An outline of the heating device will be described with reference to FIG. As the heating gas, a generally used mixed gas of LPG and O ₂ is used, and the LPG cylinder 6 and the O ₂ cylinder 7 are connected to the gas mixer 11 through the on-off valves 8 and 8 and the gas amount adjusting valves 10 and 10.
Are mixed in a predetermined mixing ratio and supplied to the micro torch 2. 9 and 9 are gas conduits. The gas flow rate from the flat opening 3 of the micro torch 2 is, as described above, the constricted portion 4
As a result, the temperature distribution of the flame 5 at the tip of the microtorch forms a flat distribution as a whole in the longitudinal direction of the flat opening 3. As a result, the fiber fusion splicing portions 18 of the optical fiber tape cable 12 and the optical fiber tape cable 13 are heated uniformly at the same temperature. FIG. 4 is a vertical cross-sectional view showing a state in which the mode-filled diameters in the fusion splicing portions 18 of the optical fibers 14 and 15 having different mode field diameters are matched by this heat treatment. The dotted line shows the state of fusion splicing of the optical fibers 14 and 15 having different mode filled diameters before the heat treatment, and the solid line shows the mutual mode filled diameters of the optical fibers 14 and 15 due to the expansion of the mode filled diameter after the heat treatment. The state of the fusion splicing part which matched is shown. Fiber 14, 1
By matching the mode field diameters of the five, the connection loss at the fusion splicing portion 18 is reduced. In FIG. 4, 14a and 15a are fiber cores, and 14b and 15b are fiber clad layers.

Next, heating experiment results using the heating device of the present invention will be described for the fusion splicing portions 18 of optical fiber tape cables having different mode filled diameters. [Experimental Example 1] 4-core high-refractive-index optical fiber tape cable [mode-filled diameter 5 μm, fiber strand diameter 125 μm
m, outer coating tape cable external dimensions 1.1 mm x 0.
4 mm] and 4-core single mode optical fiber tape cable [mode filled diameter 10 μm, fiber strand diameter 12]
5 μm, outer cover tape cable external dimensions 1.1 mm ×
Each fiber of 0.4 mm] was fusion-spliced to obtain a sample of Experimental Example 1. The flat-shaped micro-torch for heating the sample has an opening shape shown in FIG.
mm × 0.5 mm, constricted part: constricted width 0.25 mm, arranged at one place in the center of the opening], and the fusion splicing part heating time was 3 minutes. [Experimental Example 2] 8-fiber high-refractive-index optical fiber tape cable [mode-filled diameter 5 μm, fiber strand diameter 125 μm
m, outer coating tape cable external dimensions 2.2 mm x 0.
4 mm] and 8-core single mode optical fiber tape cable [mode filled diameter 10 μm, fiber strand diameter 12]
5 μm, outer tape cable outer dimensions 2.2 mm ×
Each fiber of 0.4 mm] was fusion-spliced to obtain a sample of Experimental Example 2. Figure 3 shows a flat-shaped micro torch that heats the sample.
With the opening shape shown in, the dimension structure is [Opening dimension: 2.4 mm
× 0.5 mm, constricted part: constricted width 0.25 mm, constricted interval 0.6 mm, number of constricted parts 3], and the fusion splicing part heating time was 3 minutes.

Table 1 shows the measurement results of the splice loss at the time of fusion splicing and the splice loss after the heat treatment for each of the fiber fusion spliced portions of the experimental example 1 sample and the experimental example 2 sample. The connection loss was obtained by inputting LD light having a wavelength (λ) of 1.30 μm from one end side of the optical fiber tape cable and measuring emitted light from the other end of the optical fiber tape cable with an optical power meter.

[0014] Note: The fiber numbers are assigned sequentially from one end according to the order of arrangement of the fibers of the optical fiber tape cable.

As is clear from Table 1, by heating with the flat-shaped micro-torch of the present invention, the splice loss at each fiber fusion splicing portion of the multi-core optical fiber tape cables having different mode field diameters is reduced. There is no variation between the connecting and receiving parts, which is greatly reduced.

[0016]

Since the fusion splicing portion heating device for a multi-fiber optical fiber cable of the present invention forms the opening of the micro torch in a flat shape and has the constricted portion in the flat opening, the flame tip of the micro torch is provided. The temperature distribution is made uniform over the major axis direction of the flat opening, and the fiber fusion splicing portions of the multi-fiber optical fiber tape cables can be heated uniformly at the same required temperature at the same time.
As a result, even when multi-fiber optical fiber tape cables with different mode field diameters are fusion-spliced, the splice loss at each fiber fusion-splicing part does not vary among the fiber fusion-splicing parts, and is greatly reduced. As a result, stable connection of multi-core optical fiber tape cables with different mode field diameters became possible. Furthermore, the reliability of the connection between the optical device using the semiconductor optical waveguide and the multi-core optical fiber tape cable is improved.

[Brief description of drawings]

FIG. 1 is an explanatory view showing one embodiment of a fusion splicing part heating device for a multi-fiber optical fiber tape cable according to the present invention.

FIG. 2 shows an opening cross-sectional view and a cross-sectional view of a four-core optical fiber tape cable showing an embodiment of a microtorch according to the present invention used for heating a fusion spliced portion of a four-core optical fiber tape cable.

FIG. 3 is a cross-sectional view of an opening and an 8-core optical fiber tape cable showing an embodiment of a micro torch according to the present invention used for heating a fusion spliced portion of an 8-fiber optical fiber tape cable.

FIG. 4 is a vertical cross-sectional view of an optical fiber for explaining a state in which the mode-filled diameters of the optical fibers in the fusion splicing portion of the optical fiber tape cable match.

FIG. 5 is an explanatory view of a conventional fusion splicing portion heating device for a multi-fiber optical fiber tape cable by electric discharge heating.

FIG. 6 is an explanatory diagram of a conventional fusion splicer heating device for a multi-core optical fiber tape cable using a micro torch.

[Explanation of reference numerals] 1 heating device for fusion splicing 2 micro torch 3,31 flat opening of micro torch 4 constriction 5 gas flame 6,7 gas cylinder 8 on-off valve 9 gas conduit 10 regulating valve 11 gas mixer 12, 13, 131 multi-core optical fiber tape cable 14, 15 optical fiber 14a, 15a core 15a, 15b clad layer 17 resin coating 18 fusion splicing part

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Takuhiro Ono 2-6-1, Marunouchi, Chiyoda-ku, Tokyo Furukawa Electric Co., Ltd. (72) Inventor Takeo Shimizu 2-6-1, Marunouchi, Chiyoda-ku, Tokyo Furukawa Electric Co., Ltd. (72) Inventor Kuji Yanagawa 2-6-1, Marunouchi, Chiyoda-ku, Tokyo Furukawa Electric Co., Ltd.

Claims (3)

[Claims] 1. In a fusion splicing part heating device for a multi-fiber optical fiber tape cable using a micro torch, the tip opening of the micro torch is formed into a flat shape having substantially the same outer dimensions as the optical fiber tape cable. At least one constricted portion constricted in the minor axis direction of the flat opening.
A fusion splicing part heating device for a multi-fiber optical fiber tape cable, characterized in that it is provided in places. 2. The fusion splicing part heating device for a multi-fiber optical fiber tape cable according to claim 1, wherein the constricted part is provided at a substantially central part of a flat opening of the micro torch. 3. The fusion splicing part heating device for a multi-fiber optical fiber cable according to claim 1, wherein the constricted parts are provided at substantially equal intervals in the major axis direction of the flat opening of the microtorch. .