JP2800565B2 - Hermetically sealed optical fiber terminal - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hermetically sealed optical fiber terminal used for an optical device, and more particularly, to a structure for protecting an optical fiber when manufacturing a hermetically sealed optical fiber terminal.

[0002]

2. Description of the Related Art Generally, an optical device incorporates optical components such as an optical semiconductor element and a lens / prism. Usually, those parts are stored in a package or a holder. Among these parts, in particular, an optical semiconductor element or LN
Optical waveguides and the like need to maintain moisture resistance in order to maintain their characteristics. To improve the moisture resistance of optical devices,
The most effective method is to arrange the optical components fixed with high precision in a case that is completely airtight. When such a case is hermetically sealed, seam welding can be applied to the case alone as long as the case is a metal case, so that it does not affect the components of the optical device.
A sufficient air tightness of about 0 ^-8 atm · cc / sec can be maintained. However, only the optical fiber introduction portion cannot be directly applied with a method of securing high airtightness such as seam welding from the resin material protecting the optical fiber.
For this reason, for example, in the 1990 IEICE Spring National Convention, "Ti: L with added C-232 stress relaxation function"
iNbO ₃ Device Mounting Method ”(Hiromichi Jumonji and ₃ others)
As described above, a method of hermetically sealing the optical fiber by fixing the optical fiber with a resin such as an adhesive has been adopted. However, such a resin-based hermetic sealing method requires 1
Only airtightness of about 0 ^-4 atm · cc / sec can be obtained.
It was not enough to ensure the reliability of optical devices.

[0003] As a method for achieving high airtightness of the optical fiber introduction unit, for example, 1990, Institute of Electronics, Information and Communication Engineers Spring National Convention in the "C-233 Ti: LiNbO ₃ optical modulator module" (Hakoki HiroshiSho and three other As reported in the name, there is a method in which a metal such as gold is vapor-deposited on an optical fiber and fixed to a surrounding pipe with solder. With this method, the same airtightness as seam welding can be obtained, so that the reliability of the optical device can be sufficiently ensured. However, since joining an optical fiber by soldering requires vapor deposition of a metal on the optical fiber, there are problems such as high cost and complicated processes. In addition, it is necessary to increase the strip size of the optical fiber.

Recently, a method has also been adopted in which an optical fiber is directly fixed to a metal pipe by welding a low-melting glass. FIG. 2 shows an example of a hermetically sealed optical fiber terminal using low melting point glass. In this method, first, the nylon coating 2 coated on the optical fiber 1 is partially removed to expose the optical fiber 1. Then, the low-melting glass 3 is formed, for example, into a pipe-shaped tablet, and inserted into the metal pipe 4 in a state where the optical fiber 1 peeled through the through hole of the tablet is passed through. In order to prevent the optical fiber 1 from shifting in one direction, for example, a ceramic pipe 9 provided with a through hole for positioning is press-fitted into the tip of the metal pipe 4.
The outside of the metal pipe 4 is heated, and the low-melting glass 3 inside the metal pipe 4 is melted by applying a certain amount of heat to the low-melting glass 3. Optical fiber 1, low melting point glass 3,
Since the thermal expansion coefficient is smaller in the order of the metal pipes 4, when the metal pipe 4 is cooled from the heated state, it is compressed in order from the outside. For example, when stainless steel (SUS304) is used for the metal pipe 4, the thermal expansion coefficient is 5 × 10 ⁻⁷ , 60 × 1 in the order of the optical fiber 1, the low-melting glass 3, and the metal pipe 4.
0 ^-7 and 180 × 10 ^-7 . A strong compressive force is generated due to the difference in the thermal expansion coefficient, and the optical fiber 1, the low-melting glass 3, and the metal pipe 4 can be fixed in a state of being completely adhered.
Then, a hermetically sealed optical fiber terminal sufficient for ensuring the reliability of the optical device can be manufactured.

However, in this method, it is necessary to apply heat of about 480 ° C. in order to melt the low melting point glass 3. There is a problem that micro-bending occurs. Therefore, there is a method in which the high-frequency heater 7 is used to locally heat only the tip of the metal pipe 4 so that the low-melting glass 3 can be melted in as short a time as possible so that heat is not applied to the nylon coating 2 as much as possible. Had been taken. However, simply conducting local heating cannot sufficiently suppress the heat conduction of the metal pipe, and the heat is transmitted to the nylon coating 2. Therefore, the optical fiber 1
The nylon-coated 2 metal pipe 4
The nylon coating 2 was kept away from heat by keeping it as far away as possible. In order to further suppress the conduction of heat, a cooling mechanism 8 is provided in the middle of the metal pipe 4 for cooling.

[0006]

However, these methods have not been able to satisfy the requirements such as the size of a hermetically sealed optical fiber terminal applied to an optical device. That is, in this method, it is necessary to make the entire length of the metal pipe sufficiently long. Despite the fact that the length required to achieve sufficient airtightness with low melting glass is 1-2 mm,
The total length of the metal pipe was 10 mm or more because the influence of heat had to be taken into account. In addition, the optical fiber is highly brittle and is very easy to break when handled in an exposed state, so the part protected by nylon coating is fixed in a metal pipe in normal terminal treatment, and the optical fiber is not exposed Was like that. However, in this fixing method, since the nylon coating comes into direct contact with the metal pipe, heat generated when the low-melting glass is melted is directly transmitted to the nylon coating. The heat-resistant temperature of the nylon coating for not affecting the characteristics of the optical fiber is about 70 ° C., and when the melting point of the low melting point glass of 480 ° C. is applied, the characteristics of the optical fiber are naturally lost. Therefore, it is necessary to perform a terminal treatment so that the nylon coating does not come into direct contact with the metal pipe, and a bare optical fiber is formed between the nylon coating and the metal pipe. For this reason, the handleability has been extremely reduced, and the yield has been extremely deteriorated. In addition, poor workability in manufacturing has been a bottleneck for mass production and low price.

[0007]

According to the present invention, there is provided an optical fiber, a protective member for covering an outer periphery of the optical fiber, a metal pipe provided with a through hole for passing the protective member, and a metal pipe between the metal pipe and the optical fiber. In the hermetically sealed optical fiber terminal, which is fixed by melting the low-melting glass, a through-hole having a higher melting point than the low-melting glass and passing the optical fiber is provided. A part of a first glass pipe having an outer diameter smaller than the inner diameter of the metal pipe is inserted into one end of a through hole of the metal pipe, the first glass pipe having a melting point higher than that of the low-melting glass; A portion of the second glass pipe having an inner diameter larger than the outer diameter of the glass pipe and larger than the outer diameter of the protective member for the optical fiber, protruding from the metal pipe of the first glass pipe And the protective member for the optical fiber are arranged so as to cover the same, so that the low melting point glass is melted, and the first glass pipe and the second glass pipe are integrated. May be.

[0008]

In the hermetically sealed optical fiber terminal of the present invention, a hermetically sealed optical fiber terminal is provided in which the nylon coating does not directly contact the metal pipe and the optical fiber is not exposed. That is, the length of the metal pipe is set to the minimum length necessary for fixing the low-melting glass, and the structure is such that heat from the metal pipe is not transmitted by protecting the nylon coating with the glass pipe.

A conventional hermetically sealed optical fiber terminal is configured to locally heat a metal pipe and to increase the length of the metal pipe in order to prevent heat when melting the low-melting glass from being transmitted to the nylon coating. I tried to keep the nylon coating and heat source as far away as possible. Therefore, the entire length of the metal pipe becomes unnecessarily long, and the stripped length of the optical fiber must be increased so that the nylon coating does not directly contact the metal pipe. In order to solve this problem, in the hermetically sealed optical fiber terminal of the present invention, a glass pipe having low thermal conductivity is disposed between the metal pipe and the nylon coating. Simply arranging a glass pipe cannot prevent the heat that has conducted air, so the glass pipe has a double-tube structure so that the glass pipe can be connected in the longitudinal direction of the metal pipe, and the nylon coating is fixed on the thick side The thin side is fixed to a metal pipe. As a result, the metal pipe and the nylon coating are spatially separated, and the optical fiber can be completely protected by the glass pipe. In addition, the conventional cooling mechanism can only cool the metal pipe from the outside, but in the structure of the present invention, a cooling mechanism can be provided between the metal pipe and the nylon coating, so that the space from the metal pipe can be reduced. Heat conduction can be completely removed.

[0010]

Next, the present invention will be described with reference to the drawings. FIG. 1 shows the structure of a hermetically sealed optical fiber terminal according to one embodiment of the present invention.

First, a first glass pipe 5 having different inner and outer diameters
And a second glass pipe 6 are prepared. The inner diameter of the second glass pipe 6 is substantially the same as the outer diameter of the first glass pipe 5. The melting points of the glass pipes 5 and 6 are higher than the melting point of the low-melting glass 3. About half of the length of the first glass pipe 5 is inserted into the second glass pipe 6, and the two kinds of glass pipes 5 and 6 are fixed using the low melting point glass 3 or the like. Then, the nylon coating of the tip portion of the optical fiber 1 protected by the nylon coating 2 is peeled off to expose the optical fiber 1. The glass pipe assembled on the exposed portion of the optical fiber 1 is inserted so that the second glass pipe 6 comes to the nylon coating 2 side. Then, the low-melting glass 3 formed in a tablet shape is passed through the optical fiber 1, and finally, the metal pipe 4 is passed so as to cover the tablet of the low-melting glass 3 and the first glass pipe 5.

When the tip of the metal pipe 4 is locally heated by the high-frequency heater 7, the heat of the metal pipe 4 is conducted to the low melting point glass 3 inside. When the heat conducted to the low-melting glass 3 exceeds the melting point of the low-melting glass 3, the low-melting glass 3 starts melting. The optical fiber 1 is fixed to the metal pipe 4 by melting the low melting point glass 3. As a result, the metal pipe 4 and the low melting point glass 3, the low melting point glass 3 and the optical fiber 1
Are brought into close contact with each other, and hermetically sealed and fixed at the optical fiber introduction portion.
At the same time, the metal pipe 4 and the first and second glass pipes 5 and 6 are also fixed by the molten low melting point glass 3.

The heat of the high-frequency heater 7 is transmitted to the metal pipe 4, and the low melting glass 3 in contact with the metal pipe 4 and the first
And to the second glass pipes 5, 6. Although the low melting point glass 3 is melted by the conducted heat, the first and second glass pipes 5 and 6 having a melting point higher than that of the low melting point glass 3 are not melted, and conversely suppress further heat conduction. . Therefore, the heat transmitted through the metal pipe 4 does not reach the nylon coating 2. Also, of the heat generated by the high-frequency heater 7, the heat transmitted through the air layer can be prevented from being transmitted to the nylon coating 2 by disposing the cooling mechanism 8 outside the second glass pipe 6. . As a result,
The heat of the high-frequency heater 7 can melt the low-melting glass 3 inside the metal pipe 4 without affecting the nylon coating 2 thermally. When the hermetic sealing with the low-melting glass 3 is completed, the nylon coating 2 and the second glass pipe 6 are fixed with a resin or the like to take measures against the tensile strength of the terminal and the rotation of the nylon coating 2. During this time, since the optical fiber 1 is always protected by the first and second glass pipes 5 and 6, the optical fiber 1 does not become exposed and the workability does not decrease.

The glass pipe must have a shape that can be partially inserted into the metal pipe 4 and that the glass pipe has an inner diameter larger than the outer diameter of the nylon coating 2. It need not be a double tube as in the example. For example, a stepped integral type or a normal stepless glass pipe can be used as the hermetically sealed optical fiber terminal of the present invention.

[0015]

As described above, according to the present invention, by using a glass pipe having a melting point higher than that of a low melting point glass,
When fixing the optical fiber to the metal pipe with low melting point glass, heat can be prevented from being transmitted to the protective member such as nylon coating, so that the optical characteristics of the optical fiber are not deteriorated,
In addition, the hermetically sealed optical fiber terminal can be formed without exposing the optical fiber. Further, since the positioning of the optical fiber can be reliably performed, a stable and accurate optical fiber terminal can be supplied. Further, since the glass pipe can be fixed at the same time as fixing the low-melting glass, a step of protecting the bare optical fiber is not required, and the step can be simplified. As a result, it is possible to provide an inexpensive hermetically sealed optical fiber terminal which is improved in workability in manufacturing and is excellent in mass productivity.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view showing one embodiment of the present invention.

FIG. 2 is a longitudinal sectional view showing an example of a conventional hermetically sealed optical fiber terminal.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Optical fiber 2 Nylon coating 3 Low melting point glass 4 Metal pipe 5 First glass pipe 6 Second glass pipe 7 High frequency heater 8 Cooling mechanism 9 Ceramic pipe

Claims (2)

(57) [Claims] An optical fiber, a protection member for covering an outer periphery of the optical fiber, a metal pipe provided with a through hole for passing the protection member, and a low melting point glass disposed between the metal pipe and the optical fiber. In the hermetically sealed optical fiber terminal configured and fixed by melting the low-melting glass, having a higher melting point than the low-melting glass and having a through hole through which the optical fiber passes, and the inner diameter of the metal pipe A portion of a first glass pipe having a smaller outer diameter is inserted into one end of a through hole of the metal pipe, and has a melting point higher than that of the low melting point glass and is smaller than the outer diameter of the first glass pipe. A second glass pipe having a larger inner diameter than the outer diameter of the protective member of the optical fiber,
A hermetically sealed optical fiber terminal characterized in that the glass pipe is disposed so as to cover both a portion of the glass pipe projecting from the metal pipe and a protective member of the optical fiber so as to melt the low melting point glass. 2. The hermetically sealed optical fiber terminal according to claim 1, wherein said first glass pipe and said second glass pipe are integrated.