JP2007279613A - Heat resistant fixing method of optical fiber and heat resistant optical fiber with lens - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a heat resistant fixing method of an optical fiber, which method has less fixing operation load and superior heat resistance, and further to provide a heat resistant optical fiber with a lens, which fiber is easy to manufacture and excellent in heat resistance. <P>SOLUTION: A sleeve-integrated heat resistant optical fiber (10) is ground on the tip end face to form a tapered face, with the tip end face coated with a silica micro porous solution, fixed with a lens (12), and calcined to form a silica micro porous layer (11). This optical fiber brings an extremely superior heat resistance by the silica micro porous layer (11) primarily consisting of silicon. By merely being coated with the silica micro porous solution and calcined, the optical fiber requires no high temperature as melt-sticking, thereby reducing the load of fixing operation. The silica micro porous layer (11) can transmit light. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an optical fiber heat-resistant fixing method and a heat-resistant optical fiber with a lens, and more specifically, an optical fiber heat-resistant fixing method that requires less fixing work and has excellent heat resistance, is easy to manufacture, and has excellent heat resistance. The present invention relates to a heat resistant optical fiber with a lens.

2. Description of the Related Art Conventionally, an optical fiber with a lens in which a lens is fused to an end surface of an optical fiber is known (see, for example, Patent Document 1 and Patent Document 2).
JP 2005-31477 A JP 2004-198976 A

In the conventional optical fiber with a lens, a high heat resistance is obtained because the lens is fixed to the front end surface of the optical fiber by fusion. However, there is a problem that the burden of fusion work is large.
On the other hand, if the lens is fixed to the end face of the optical fiber using an organic adhesive, the burden of fixing work can be reduced. However, there is a problem that high heat resistance cannot be obtained.
SUMMARY OF THE INVENTION An object of the present invention is to provide a heat-resistant optical fiber fixing method that requires less fixing work and is excellent in heat resistance, and a heat-resistant optical fiber with a lens that is easy to manufacture and excellent in heat resistance.

In a first aspect, the present invention relates to a sleeve integrated type in which an inorganic sleeve or a metal sleeve (2) is integrated with an end of a quartz optical fiber (1) comprising a core (1r) and a clad (1d). Provided is an optical fiber heat-resistant fixing method characterized in that the tip surface of an optical fiber (10) is fixed to an inorganic optical member or a metal optical member (12) through a silica microporous layer (11). .
In the optical fiber heat-resistant fixing method according to the first aspect, the silica optical fiber (1) and the inorganic optical member or metal optical member (12) are fixed by the silica microporous layer (11). Since this silica microporous body layer (11) has silicon as a main component, it has extremely high heat resistance. In addition, since the formation of the silica microporous layer (11) is merely performed by applying a silica microporous solution and sintering, it is not necessary to raise the temperature as high as fusion, and the burden of fixing work can be reduced. The silica microporous body layer (11) includes voids, and light passes through the silica microporous body layer (3).

In a second aspect, the present invention relates to the optical fiber fixing method according to the first aspect, wherein the end surface of the sleeve-integrated optical fiber (10) is inclined with respect to a plane perpendicular to the optical axis. An optical fiber heat-resistant fixing method is provided.
In the optical fiber heat-resistant fixing method according to the second aspect, since the tip end surface of the sleeve-integrated optical fiber (10) is an inclined surface, the silica microporous layer (11) becomes wedge-shaped and stability is increased. The influence of light reflection on the surface can be reduced.

In a third aspect, the present invention provides the optical fiber heat-resistant fixing method according to the first or second aspect, wherein the silica-based optical fiber (1) and the inorganic sleeve or the metal sleeve (2) are made of silica. Provided is an optical fiber heat-resistant fixing method, wherein the optical fiber heat-fixing method is characterized in that the optical fiber is fixed integrally through a microporous layer (3).
In the optical fiber heat-resistant fixing method according to the third aspect, the silica-based optical fiber (1) and the inorganic-based sleeve or the metal sleeve (2) are integrally fixed together by the silica microporous layer (3). Since this silica microporous layer (3) is mainly composed of silicon, it has extremely high heat resistance. Further, since the silica microporous layer (3) includes voids, it has heat insulation and buffering properties, and heat and stress applied to the sleeve (2) from the outside are hardly transmitted to the optical fiber (1).

In a fourth aspect, the present invention provides the optical fiber heat-resistant fixing method according to any one of the first to third aspects, wherein the inorganic optical member or the metallic optical member (12) is a lens or a waveguide. An optical fiber heat-resistant fixing method is provided.
In the optical fiber heat-resistant fixing method according to the fourth aspect, a heat-resistant optical fiber with a lens can be suitably manufactured. In addition, the optical fiber can be suitably fixed to the waveguide.

In a fifth aspect, the present invention relates to a sleeve integrated type in which an inorganic sleeve or a metal sleeve (2) is integrated with an end of a quartz optical fiber (1) comprising a core (1r) and a clad (1d). Provided is a heat-resistant optical fiber with a lens (100), characterized in that a lens (12) is fixed to a front end face of an optical fiber (10) through a silica microporous layer (11).
In the heat-resistant optical fiber with lens (100) according to the fifth aspect, the quartz optical fiber (1) and the inorganic optical member or metal optical member (12) are fixed by the silica microporous layer (11). Since this silica microporous body layer (11) has silicon as a main component, it has extremely high heat resistance. In addition, since the formation of the silica microporous layer (11) is merely performed by applying a silica microporous solution and sintering, it is not necessary to raise the temperature as high as fusion, and the burden of fixing work can be reduced. The silica microporous body layer (11) includes voids, and light passes through the silica microporous body layer (3).

In a sixth aspect, the present invention relates to the heat resistant optical fiber with lens (100) according to the fifth aspect, wherein a front end surface of the sleeve-integrated optical fiber (10) is a plane perpendicular to the optical axis. Provided is a heat-resistant optical fiber (100) with a lens that is inclined.
In the heat-resistant optical fiber with lens (100) according to the sixth aspect, since the tip end surface of the sleeve-integrated optical fiber (10) is inclined, the silica microporous layer (11) is wedge-shaped and stable. As it increases, the influence of light reflection on the tip surface can be reduced.

In a seventh aspect, the present invention relates to the heat-resistant optical fiber with lens (100) according to the fifth or sixth aspect, wherein the sleeve-integrated optical fiber (10) is a silica-based optical fiber (1), An inorganic sleeve or metal sleeve (2) through which the silica-based optical fiber (1) is inserted, and a silica micro that integrally fixes the silica-based optical fiber (1) and the inorganic sleeve or metal sleeve (2) together. Provided is a heat-resistant optical fiber (100) with a lens comprising a porous body layer (3).
In the heat-resistant optical fiber with lens (100) according to the seventh aspect, the quartz optical fiber (1) and the inorganic sleeve or the metal sleeve (2) are integrally fixed together by the silica microporous layer (3). Since this silica microporous layer (3) is mainly composed of silicon, it has extremely high heat resistance. Further, since the silica microporous layer (3) includes voids, it has heat insulation and buffering properties, and heat and stress applied to the sleeve (2) from the outside are hardly transmitted to the optical fiber (1).

According to the optical fiber heat-resistant fixing method of the present invention, not only extremely high heat resistance can be obtained, but the burden of fixing work can be reduced.
According to the heat-resistant optical fiber with a lens of the present invention, not only extremely high heat resistance is obtained, but also the manufacture becomes easy.

  Hereinafter, the present invention will be described in more detail with reference to embodiments shown in the drawings. Note that the present invention is not limited thereby.

FIG. 1 is a cross-sectional view showing a heat-resistant optical fiber with lens 100 according to the first embodiment. FIG. 2 is a front view of the same. FIG. 3 is a rear view of the same.
In this heat-resistant optical fiber with lens 100, a lens 12 is fixed to the front end surface of the sleeve-integrated heat-resistant optical fiber 10 through a silica microporous layer 11.

The sleeve-integrated heat-resistant optical fiber 10 includes a silica-based optical fiber 1 including a core 1r and a cladding 1d, an inorganic sleeve or metal sleeve 2 through which the silica-based optical fiber 1 is inserted, and a silica-based optical fiber 1 and an inorganic sleeve. Alternatively, it comprises a silica microporous layer 3 that is integrally fixed to the metal sleeve 2.
The distal end surface of the sleeve-integrated heat-resistant optical fiber 10 is inclined with respect to a plane orthogonal to the optical axis.

  As a numerical example, the diameter of the core 1r of the silica-based optical fiber 1 is 10 μm, and the diameter of the cladding 1d is 125 μm. The inorganic sleeve or metal sleeve 2 has an inner diameter of 126 μm and an outer diameter of 1.8 mm. The inclination angle of the distal end face of the sleeve-integrated heat resistant optical fiber 10 is 8 ° with respect to a plane perpendicular to the optical axis.

  The silica microporous layers 3 and 11 have a large number of micropores having an average distribution of 2 nm.

The heat-resistant optical fiber with lens 100 is manufactured by the following procedure.
(1) A silica microporous material solution is coated on the outer surface of the silica-based optical fiber 1, and the silica-based optical fiber 1 is inserted into an inorganic sleeve or a metal sleeve 2 and baked to form a silica microporous layer 3. Thus, the sleeve-integrated heat-resistant optical fiber 10 is manufactured. Note that if the quartz optical fiber 1 or the inorganic sleeve or the metal sleeve 2 is inserted while applying ultrasonic vibration, the insertion operation becomes easy.
(2) The tip surface of the sleeve-integrated heat-resistant optical fiber 10 is polished to be a tapered surface, and the tip surface is coated with a silica microporous solution, the lens 12 is fixed, and baked to form the silica microporous layer 11. Form.

  A method for synthesizing a silica microporous material solution has been published in “Chemical Engineering Society 34th Autumn Meeting, 2001”. Moreover, it describes in Unexamined-Japanese-Patent No. 2004-292190.

  According to the heat-resistant optical fiber with lens 100 of Example 1, extremely excellent heat resistance is obtained by the silica microporous layers 3 and 11 containing silicon as a main component. Moreover, since the silica microporous material solution is simply applied and sintered, it is not necessary to use a high temperature as much as the fusion, and the burden of the fixing work can be reduced.

The silica microporous layer 11 includes voids, and light can pass through the silica microporous layer 11.
Further, since the silica microporous layer 3 includes voids, it has heat insulation and buffering properties, and heat and stress applied to the inorganic sleeve or the metal sleeve 2 from the outside are not easily transmitted to the quartz optical fiber 1. Durability is improved.

FIG. 4 is a cross-sectional view illustrating the optical fiber heat-resistant fixing method according to the second embodiment.
The distal end surface of the sleeve-integrated heat-resistant optical fiber 10 is fixed to the waveguide 12 via the silica microporous layer 11.

  According to the optical fiber heat-resistant fixing method of Example 2, extremely excellent heat resistance is obtained by the silica microporous layer 11 mainly composed of silicon. Moreover, since the silica microporous material solution is simply applied and sintered, it is not necessary to use a high temperature as much as the fusion, and the burden of the fixing work can be reduced.

  The silica microporous layer 11 includes voids, and light passes through the silica microporous layer 11.

  The optical fiber heat-resistant fixing method of the present invention can be used for manufacturing a communication fiber of a WDM system. The heat-resistant optical fiber with a lens of the present invention can be used as a communication fiber for a WDM system.

It is sectional drawing which shows the heat-resistant optical fiber with a lens concerning Example 1. FIG. It is a front view which shows the heat-resistant optical fiber with a lens concerning Example 1. FIG. It is a rear view which shows the heat-resistant optical fiber with a lens concerning Example 1. FIG. It is sectional drawing which shows the optical fiber heat-resistant fixing method concerning Example 2. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Quartz type optical fiber 1r Core 1d Clad 2 Inorganic type | system | group sleeve or metal sleeve 3 Silica micro porous body layer 10 Sleeve integrated heat resistant optical fiber 11 Silica micro porous body layer 12 Lens or waveguide 100 Heat resistant optical fiber with a lens

Claims (7)

The tip end surface of the sleeve-integrated optical fiber (10) formed by integrating the inorganic sleeve or the metal sleeve (2) at the end of the quartz optical fiber (1) composed of the core (1r) and the clad (1d), An optical fiber heat-resistant fixing method, comprising fixing to an inorganic optical member or a metal optical member (12) through a silica microporous layer (11). The optical fiber heat-fixing method according to claim 1, wherein the front end surface of the sleeve-integrated optical fiber (10) is inclined with respect to a plane perpendicular to the optical axis. The optical fiber heat-resistant fixing method according to claim 1 or 2, wherein the silica-based optical fiber (1) and the inorganic sleeve or metal sleeve (2) are interposed via a silica microporous layer (3). An optical fiber heat-resistant fixing method, wherein the optical fiber is fixed integrally. The optical fiber heat-resistant fixing method according to any one of claims 1 to 3, wherein the inorganic optical member or the metal optical member (12) is a lens or a waveguide. Method.
On the end surface of the sleeve-integrated optical fiber (10) formed by integrating an inorganic sleeve or a metal sleeve (2) at the end of the quartz optical fiber (1) composed of the core (1r) and the clad (1d), A heat-resistant optical fiber with lens (100), wherein a lens (12) is fixed via a silica microporous layer (11). 6. The heat resistant optical fiber with a lens according to claim 5, wherein the end surface of the sleeve-integrated optical fiber is inclined with respect to a plane perpendicular to the optical axis. Heat-resistant optical fiber (100) with attachment. The heat-resistant optical fiber with lens (100) according to claim 5 or 6, wherein the sleeve-integrated optical fiber (10) is inserted through the silica-based optical fiber (1) and the silica-based optical fiber (1). An inorganic sleeve or metal sleeve (2), and a silica microporous layer (3) for integrally fixing the quartz optical fiber (1) and the inorganic sleeve or metal sleeve (2) together. A heat-resistant optical fiber with a lens (100),

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