JPH11287922A - Method and device for connecting optical fiber - Google Patents

Abstract

PROBLEM TO BE SOLVED: To connect first and second optical fibers respectively composed of different glass materials through fusion splicing by softening or melting the connection end section of the first fiber by heating. SOLUTION: The optical axes of a first optical fiber (non-quartz optical fiber) 1 and a second optical fiber (quartz optical fiber) 2 are aligned so as to be coincident on a connection end face. As the non-quartz optical fiber, there are tellurite glass optical fiber and Zr fluoride glass fiber or the like. Discharging occurs between electrodes 4 for arc discharge, the optical fiber 2 is made closer to the tellurite glass optical fiber 1 during discharging and a distance between terminal parts is turned to '0'. Only the terminal part of the optical fiber 1 can be made molten by heating due to arc discharging and this end face is connected in contact with the end face of the optical fiber 2. As a method for heating the terminal part of the optical fiber, a heating method due to laser beam incidence or high frequency induction in addition to the arc discharge is used.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for connecting an optical fiber, which is an amplification medium used in an optical fiber amplifier, to a silica-based fiber and an optical fiber having an optical control function such as wavelength conversion. The present invention relates to a method for connecting two optical fibers made of different glass materials such as a connection and an optical fiber connecting device.

[0002]

2. Description of the Related Art An optical fiber using tellurite glass, Zr-based fluoride glass, In-based fluoride glass, or chalcogenide glass has a 1.3 μm band which cannot be realized by quartz glass by adding Pr ions to a core. It is known that optical amplification is possible, and that broadband amplification in the 1.55 μm band, which cannot be realized with quartz glass even when Er ions are added, is possible. Further, tellurite glass and chalcogenide glass have been attracting attention as materials for high-speed optical switches due to their large third-order nonlinear effects, and wavelength conversion devices have attracted attention as high-performance materials in optical communication fields, such as ultra-high-speed optical switches. Have been.

In order to use the above optical fiber as a communication component, it is necessary to connect the optical fiber to a transmission medium such as a silica-based optical fiber with low loss. The optical fiber can be connected by fixing the fiber to a V-groove block or ferrule, polishing the end face, aligning the optical axis, filling an adhesive between the end faces, and fixing the connector. There is known a method for mechanical connection. The connection method using the V-groove block or ferrule requires a step of polishing the fiber connection end face in addition to the step of fixing the fiber to the V-groove block or ferrule. The material that constitutes the V-groove block and ferrule,
Because the mechanical properties of the connection adhesive and the fiber material are different, the fiber connection end face is polished and jumps out of the fiber end face. This leads to an obstacle in controlling the fiber end face spacing at the time of connection, which causes an increase and variation in connection loss. For this reason, in the connection method using a normal V-groove block or ferrule, the connection loss is 0.3 to 1
It is known that in dB, there is variation for each connection. In a device utilizing optical amplification or nonlinear optical effect, it is necessary to increase the optical electric field intensity at the center of the core as long as the efficiency can be increased. In a connection using an adhesive, the high optical electric field strength causes deterioration of the adhesive, resulting in an increase in connection loss or disconnection in long-term use. Furthermore, the refractive index difference between the core and clad of the fiber is larger than that of a normal transmission fiber, and the core diameter is 2
It is extremely small, about μm. For this reason, the amount of change in the connection loss with respect to the misalignment of the fiber is large, and the connection loss also changes due to a change in temperature from room temperature. This is because, in the connection method described above, since the connection is made as a composite of several types of materials, the expansion and contraction of each material due to a temperature change varies, and the optical axis shifts. In the above connection method, -40 to +
For a temperature change of 75 ° C., the connection loss fluctuates by about ± 0.5 dB, and there is a problem that the characteristics of the device fluctuate according to the temperature fluctuation in the use environment.

[0004]

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to propose a method and an apparatus for splicing optical fibers made of different glass materials by fusion. It is in.

[0005]

The invention of a method for connecting optical fibers according to the present invention is a method for connecting two optical fibers, at least one of which is a non-quartz optical fiber,
The optical axis of the first fiber which is a non-quartz optical fiber and the first fiber
In the state where the optical axis of the second fiber and the optical axis of the second fiber made of
By heating at least the connection end portion of the first fiber among the connection end portions of the two optical fibers, the connection end portion of the first fiber is softened or melted, and the two optical fibers are fusion-spliced. Features.

Here, two optical fibers can be fusion-spliced in a state where the connection end portion of the second optical fiber is not softened or melted.

Further, the heating temperature of the connection end portion of the optical fiber can be equal to or higher than the lowest glass transition temperature of the glass constituting the non-quartz optical fiber.

[0008] The non-quartz optical fiber may be made of one selected from the group consisting of tellurite glass fiber, Zr-based fluoride glass fiber, In-based fluoride glass fiber, and chalcogenide glass fiber.

The optical axis of the first fiber and the optical axis of the second fiber are inclined at different angles with respect to the vertical axis of the connection end face, respectively, and the optical axis of the first fiber is perpendicular to the connection end face of the first fiber. The relationship between the tilt angle θ ₁ with respect to the axis and the tilt angle θ ₂ with respect to the vertical axis of the connection end face of the optical axis of the second fiber is represented by n ₁ as the core refractive index of the first fiber and n as the core refractive index of the second fiber. when you and n _2,

[0010]

## EQU2 ## The connection can be made so as to satisfy the Snell's law of (sin θ ₁ ) / (sin θ ₂ ) = n ₂ / n ₁ within a range of ± 10%.

The heating of the optical fiber connection end portion can be performed by arc discharge.

Further, the heating of the optical fiber connection end portion can be performed by incidence of a laser beam.

Here, the laser beam can be incident by a carbon dioxide gas laser.

Further, the heating of the optical fiber connection end portion can be performed by high frequency induction heating.

Further, the heating of the optical fiber connection end portion can be performed by energizing heating of a resistor disposed near the connection end portion of the optical fiber.

After the first fiber and the second fiber are aligned, the distance between the ends of the optical fibers when the connection ends of the optical fibers are heated may be 0 to 10 μm.

When the distance between the ends of the optical fiber is zero, a pressing load of 10 g or less can be applied between the ends of the optical fiber in the axial direction of the optical fiber.

After the first fiber and the second fiber are aligned, at least the connection end portion of the first fiber of the first fiber and the second fiber is heated or heated. The distance between the optical fiber ends can be changed.

Further, the periphery of the connection portion between the first fiber and the second fiber is made of glass or glass along the optical axis of the optical fiber.
It can be reinforced by a member made of at least one material selected from the group consisting of an inorganic crystal material, a polymer material, and a metal.

The invention of the optical fiber connecting apparatus of the present invention is an apparatus for connecting a first fiber which is a non-silica type optical fiber and a second fiber made of glass different from the first fiber, and comprises a gas introducing device. Means, a first fiber and a second fiber.
Means for aligning the optical axes of the first and second fibers so that they coincide with each other at the connection end face, and means for heating at least the connection end portion of the first fiber of the first fiber and the second fiber. It is characterized by.

Here, the means for centering includes a plane including an optical axis of the first fiber and a vertical axis of a connection end face of the first fiber, and a connection between the optical axis of the second fiber and the second fiber. A rotation mechanism for rotating the first fiber holder for fixing the first fiber and the second fiber holder for fixing the second fiber, such that the plane including the vertical axis of the end face coincides with the rotation axis; An optical fiber end face for any one of the optical fibers to have a moving mechanism for three-dimensionally translating the fiber holder, and to make the connection end face of the first fiber and the connection end face of the second fiber parallel; May be provided with a rotation mechanism that rotates two-dimensionally with the center of rotation as the center of rotation.

Here, the gas introduction means has a gas introduction port, and the gas introduction port is provided to maintain a portion where the ends of the first fiber and the second fiber are installed in a predetermined atmosphere. A drying gas can be introduced.

Further, the optical fiber connection device of the present invention can further include a detection mechanism for detecting a weight applied to the optical fiber to at least one of the fiber holders for fixing the optical fiber.

[0024]

DESCRIPTION OF THE PREFERRED EMBODIMENTS In the present invention, after the optical axes of two optical fibers (a first fiber and a second fiber) are aligned, the ends of at least one of the optical fibers are softened by heating. Two optical fibers are connected. Assuming that the non-quartz optical fiber is a first fiber and the silica optical fiber is a second fiber, the optical axes of the first fiber and the second fiber are aligned so that they coincide with each other at the connection end face, and then heated. At least the end of the first fiber (non-quartz optical fiber) is softened and connected to the end of the second fiber.

Here, examples of the non-quartz optical fiber include tellurite glass optical fiber, Zr-based fluoride glass fiber, In-based fluoride glass optical fiber, chalcogenide glass fiber and the like. These fibers are Er, Pr, Tm, Ho, Yb, Tb, Nd, E
u or the like may be added.

The non-quartz optical fiber and the quartz optical fiber may be made of glass made of one kind of material, or may be made of glass made of plural kinds of material. In such a case, in order to heat and melt the connection end portion of the optical fiber, it is preferable to heat at a temperature equal to or higher than the glass transition temperature of the material having the lowest glass transition temperature among the materials constituting glass.

As the method of heating the end of the optical fiber, a method of heating by arc discharge, laser beam injection, high-frequency induction, energization of a resistor placed near the connection end of the optical fiber, or the like is used. For heating by laser light incidence, a laser having an oscillation wavelength transmitting through a quartz-based optical fiber is preferably used, and examples thereof include a carbon dioxide gas laser and a Yb fiber laser. In high-frequency induction heating, a high-frequency coil or the like can be used by installing it around the fiber connection. In heating by energizing the resistor, resistance heating by installing a resistor such as a Kanthal wire near the connection can be used. Used.

In the present invention, the distance between the connection ends of the two optical fibers during heating is preferably from 0 to 20 μm, and particularly preferably from 0 to 10 μm. However, the distance between the connection ends of the two optical fibers is 0 μm.
In the case of m, it is preferable to apply a pressing load of 0 to 10 g between the two optical fibers in the axial direction of the fibers. The distance between the connection ends of the two optical fibers can be adjusted before the connection end portion is softened after the optical axis is aligned, but the connection end portion of the optical fiber is heated or heated. It can be adjusted later.

In the present invention, it is particularly preferable that the connection of the two optical fibers is in a relation satisfying Snell's law. This will be specifically described below.

When a non-quartz optical fiber and a silica optical fiber are connected, since the refractive index of the core is different between the two, low-loss and low-reflection connection can be realized by light reflection of propagating light at the connection interface. Need to be considered. In a connection in which the connection interface 104 of the fibers is perpendicular to the optical axis as shown in FIG. 1A, Fresnel reflection occurs due to the difference in the refractive index between the cores of the two fibers to be connected, and this becomes the reflected return light 103. For example, when a tellurite glass fiber with a large core refractive index (core refractive index of about 2.1) and a silica-based fiber with a small core refractive index (core refractive index of about 1.5) are connected, the return loss is 16 dB. . On the other hand, if the connection interface 104 is inclined with respect to the optical axis as shown in FIG. 1B, the reflected light at the connection interface is emitted outside the core and does not become return light, so that the return loss is improved. I do. However, since light transmitted through the connection interface is refracted at the connection interface, it propagates in a direction deviated from the optical axis direction, and the transmission characteristics from the non-quartz optical fiber to the silica optical fiber deteriorate. However, when the optical axes of the non-quartz optical fiber and the silica optical fiber are inclined at a predetermined angle so as to satisfy Snell's law with respect to the vertical axis of the connection end face 104 as shown in FIG. -Low reflection connection can be realized. That is, as for the light 101 that has propagated through the non-quartz fiber and entered the connection interface, the refracted transmitted light 102 propagates in the optical axis direction of the quartz optical fiber, and the reflected return light 103 is emitted outside the core. Therefore, connection with low loss and low reflection can be realized.

For example, the optical axis of the non-silica optical fiber (first fiber) and the optical axis of the silica optical fiber (second fiber) are perpendicular to the connection end face of the optical fiber (hereinafter referred to as "vertical axis"). respect are inclined at different angles, the relationship between the inclination angle theta ₂ with respect to the vertical axis of the optical axis of the tilt angle theta ₁ and second fiber relative to the vertical axis of the optical axis of the first fiber, the first The core refractive index of the optical fiber
₁ , when the refractive index of the second optical fiber core is n ₂ ,

[0032]

## EQU3 ## The connection is made so as to satisfy the Snell's law of (sin θ ₁ ) / (sin θ ₂ ) = n ₂ / n ₁ (1). Here, a desired combination of the inclination angles θ ₁ and θ ₂ can be selected, but the return loss can be increased by using the largest possible combination of values.

However, since it is actually affected by the equivalent refractive index of the core of the optical fiber, (sin θ ₁ ) / (sin θ ₂ )
Does not necessarily exactly match n ₂ / n _1, and in practice, the value of (sin θ ₁ ) / (sin θ ₂ ) should be within ± 10% of n ₂ / n _1. I just need. However, its value is ± 2
% Is preferable.

In the present invention, gas introducing means, and means for adjusting the connection of the two optical fibers so that the optical axis of the first fiber and the optical axis of the second fiber coincide at the connection end face, The connection can be made by using a connection device having means for heating at least one end of the optical fiber. However, the alignment means includes a plane including the optical axis of one optical fiber and the vertical axis of the connection end face of the optical fiber, and the optical axis of the other optical fiber and the vertical axis of the connection end face of the optical fiber. A rotation mechanism for rotating a first fiber holder for fixing one optical fiber and a second fiber holder for fixing the other optical fiber, and the second fiber holder are three-dimensionally aligned with the plane. It has a moving mechanism for parallel translation, and in order to make the connection end face of one optical fiber and the connection end face of the other optical fiber parallel, the center of the end face of the optical fiber with respect to any of the optical fibers is used as the rotation center It has a rotation mechanism that rotates in a plane.

A gas is introduced into the apparatus from a gas inlet, and two optical fibers are connected in a gas atmosphere. Examples of the gas to be filled include dry nitrogen gas. For example, when the fiber to be connected is a fluoride optical fiber, control of the atmosphere in such a connection device is important. A connection device preferably used in the present invention will be described with reference to FIG. FIG. 2 is a plan view showing the concept of the device of the present invention.

In FIG. 2, reference numeral 1 denotes a first fiber;
Denotes a second fiber, 3a denotes a first fiber holder for holding a first fiber, and 3b denotes a second fiber holder for holding a second fiber. The first fiber holder is set so that the optical axis of the optical fiber coincides with the Z axis in FIG. 2, and has a rotation mechanism that can rotate as shown by an arrow 6 with respect to the Z axis. The second fiber holder includes a moving mechanism that can move in parallel along the X axis, the Y axis, and the Z axis, a rotation mechanism that can rotate as shown by an arrow 6 ′ with respect to the optical axis of the second fiber, and a second mechanism. With the center of the connection end face of the fiber as the center of rotation, YZ as shown by arrow 7
It has a rotation mechanism that can rotate in a plane. Reference numeral 4 denotes an electrode for arc discharge, which is installed so that the fiber connection end face can be heated. In the present invention, heating by laser beam incidence or the like may be used instead of arc discharge. In that case, such heating means is appropriately replaced. 5
Is a gas inlet.

A camera or the like for observing the connection portion is provided vertically above the fiber connection portion.

It is preferable that the connection device of the present invention further includes a mechanism for detecting a load applied to the fiber to at least one of the fiber holders 3a and 3b, for example, a load cell. In the present invention, it is preferable that the connection portion between the two fibers is reinforced around the fiber along the optical axis with a member made of a material such as glass, an inorganic crystal material, a polymer material, and a metal. However, the reinforcing member may be made of not only one kind but also two or more kinds of materials.

According to the connection method of the present invention, since it is not necessary to fix to a different material such as a V-groove or a ferrule, the steps of assembling and polishing can be omitted. Further, since the connection end faces of the fibers are in close contact, the connection loss can be reduced, and the loss fluctuation due to temperature fluctuation can be reduced. According to this connection, since an organic material such as an adhesive does not exist in a portion where light is guided, there is an advantage that there is no long-term increase in connection loss even with a high light input.
In addition, by using the connection device of the present invention, it is possible to easily connect a non-quartz optical fiber to a silica-based optical fiber, and it is possible to use the non-quartz-based fiber like a conventional silica fiber for communication. There are advantages to

Hereinafter, the present invention will be described in detail with reference to examples. However, the examples disclosed below are merely exemplifications of the present invention.
It does not limit the scope of the invention in any way.

Example 1 Tellurite glass optical fiber doped with Er as a first fiber (glass system is Te
O ₂ —ZnO—Na ₂ O, core refractive index 2.1, mode field diameter 5 μm, Er added concentration 4000 pp
m, the fiber coating was a UV resin, and the second fiber was a silica-based optical fiber (core refractive index: 1.5, mode field diameter: 5 μm, coating: UV resin). FIG. 3 shows an outline of the connection. In FIG. 3, 1 is a tellurite glass optical fiber as a first fiber, 2 is a silica-based optical fiber as a second fiber, 3a is a first fiber holder, 3b is a second fiber holder, and 4 is an arc. This is a discharge electrode. The atmosphere around the connection was dry nitrogen gas. The distance between the connection ends of the two optical fibers 1 and 2 is about 1
μm. Laser light having a wavelength of 1.3 μm incident on the tellurite glass optical fiber was detected at the end of the silica-based optical fiber, and the silica-based optical fiber was moved in the XY plane and aligned so that the intensity became maximum. Thereafter, discharge was caused between the electrodes for arc discharge, and the quartz optical fiber was brought closer to the tellurite glass optical fiber during the discharge, and the distance between the ends was set to zero. Only the end of the tellurite glass optical fiber was brought into a molten state by heating by the arc discharge, and this end was brought into contact with the end of the silica-based optical fiber and connected.

The splice loss was measured at 1.3 μm without Er absorption of the Er-doped tellurite glass optical fiber. 10
Connection points were connected in series and the connection loss was evaluated.
The connection loss was 0.015 dB on average (excluding reflection loss due to refractive index mismatch). When the connection strength was measured with a tensile tester, the connection strength was 250 MPa.

However, the melting condition of the tellurite glass optical fiber was adjusted by both the discharge voltage of the arc discharge and the distance between the electrodes. Connection is possible at least at the temperature at which the tellurite glass optical fiber softens (at least the glass transition temperature, around 300 ° C.), and by heating above the liquidus temperature of the tellurite glass, the connection loss is 0.1 dB or less. And a connection strength of 150 MPa. Further, if the interval between the fiber end faces during discharge is between 0 and 20 μm, 0.1 d
Although a connection loss of B or less and a connection strength of 150 MPa could be realized, if it is larger than 20 μm, the tip of the tellurite glass optical fiber becomes spherical, the contact area of the connection point becomes small, and sufficient adhesive strength is obtained. However, the fiber core also tends to be deformed, and good connection cannot be realized.

Here, a tellurite glass optical fiber in which Er was added to the core was used, but instead of Er, Pr,
One or two of Tm, Ho, Yb, Tb, Nd, and Eu
The same connection as in the present embodiment was possible with a fiber containing more than one kind or a fiber not containing these. The same connection was also made for a Zr-based fluoride glass optical fiber, an In-based fluoride optical fiber, and a chalcogenide optical fiber containing at least one of these rare earth ions, and a similarly good connection was possible.

(Example 2) A connection was made with a silica-based optical fiber in the same manner as in Example 1 except that the first fiber was replaced with a Zr-based fluoride glass optical fiber. However, the Zr-based fluoride glass optical fiber _{used, ZrF 4 -BaF 2 -LaF 3 -YF} 3 -AlF 3
-LiF-NaF-based, the refractive index of the core is 1.55,
It has a mode field diameter of 4 μm and is coated with a UV resin. Dry nitrogen (moisture dew point-
70 ° C.).

The connection loss measured at 1.3 μm was 0.03 dB, and the connection strength was 120 MPa.

When the atmosphere in the connection device was changed to an atmosphere containing water (atmosphere), the end of the fluoride fiber was devitrified due to crystallization, and good connection could not be realized.

(Example 3) A connection with a quartz optical fiber was performed in the same manner as in Example 1 except that the first fiber was replaced with an In-based fluoride glass optical fiber. However, the In-based fluoride fiber used was InF
_{3 -GaF 3 -LaF 3 -ZnF 2 -PbF} 2 -BaF
_{It is a 2-} SrF ₂ —YF ₃ —NaF system, in which the core has a refractive index of 1.65, a mode field diameter of 4.5 μm, and is coated with a UV resin.

When the connection loss was measured at 1.3 μm, it was 0.035 dB, and the connection strength was 140 MPa. As in the case of Example 2, a good connection could be realized by setting the atmosphere around the connection portion to a dry atmosphere.

Example 4 A quartz optical fiber was connected in the same manner as in Example 1 except that the first fiber was replaced with an As-S-based chalcogenide glass fiber. However, the core used had a refractive index of 2.4, a mode field diameter of 3 μm, and was coated with a UV resin.

When the connection loss was measured at 1.3 μm, it was 0.035 dB, and the connection strength was 140 MPa. As in the case of Example 2, a good connection could be realized by setting the atmosphere around the connection portion to a dry atmosphere.

(Example 5) As in Example 1, a tellurite glass optical fiber was used as the first fiber, and a second fiber was used.
A silica-based optical fiber was used as the fiber. The connection end face of both fibers is 90 ° to the optical axis with a fiber cleaver
After being cut so as to have an angle of, it was used for connection. At the time of connection, after bringing the distance between the fiber ends close to 1 μm,
The center was adjusted to a position where light incident from the tellurite glass optical fiber was most efficiently coupled on a plane (XY plane) perpendicular to the optical axis. Then, the quartz optical fiber is moved to its optical axis (Z
After the silica-based optical fiber was brought into contact with the tellurite glass optical fiber, the silica-based optical fiber was pressed against the tellurite glass optical fiber until a weight of 5 g was applied. Thereafter, the connection end was heated by the carbon dioxide laser using a mirror arranged so that the incident carbon dioxide laser was focused on the fiber connection part. The heating melts the end of the tellurite glass optical fiber and releases the monitored load. At this time, the tellurite glass optical fiber was pulled back by 1 μm simultaneously with the heating so that the tellurite glass optical fiber was not deformed. . By this operation, the outer shape of the tellurite glass optical fiber could be connected without changing the core without changing the outer shape.

The connection loss of the connection thus obtained was 0.01 dB, and a good connection could be realized. The method of the present embodiment can suppress deterioration of the optical coupling characteristics due to deformation of the end portion of the tellurite glass optical fiber during heating as compared with the method of the first embodiment. However, as compared with the method of the first embodiment, the smoothness of the end face of the fiber used for the connection has a great influence on the connection loss. Therefore, it is desirable to inspect the fiber end face after cutting the fiber end face and confirm the smoothness before connecting the fiber.

Also in this embodiment, the connection can be made by setting the heating temperature of the end of the tellurite glass optical fiber to the glass transition temperature or higher, and good connection strength can be obtained by heating to the liquidus temperature of the tellurite glass or higher. Can be obtained.

The pressing load applied to the fiber end face is 0 to
Although it was possible up to about 40 g, with a load of 10 g or more, fiber displacement and end face breakage occurred depending on the holding state of the fiber and the angle of the end face. Therefore, the weight is 0
It is desirable to be in the range of 10 g.

The same connection characteristics could be realized by replacing the first fiber with a Zr-based fluoride glass optical fiber, an In-based fluoride glass optical fiber, or a chalcogenide glass optical fiber.

Further, the method of heating the end of the fiber was changed from arc discharge to laser injection, high-frequency heating, and energization heating of the resistor, but the same result could be obtained. However, the laser incident on the fiber required a higher incident power than the method of the first embodiment. Also, Zr
In the case of a system fluoride glass optical fiber and an In system fluoride glass optical fiber, the atmosphere around the connection is dew point -4.
By keeping the atmosphere at 0 ° C. or lower in a dry atmosphere, a good connection loss could be obtained.

(Example 6) As in Example 1, a tellurite glass optical fiber was used as the first fiber, a silica-based optical fiber was used as the second fiber, and the optical fiber was connected using the optical fiber connecting device shown in FIG. Made the connection. The end face of the tellurite glass optical fiber was cut so that the angle between the vertical axis and the optical axis was 5.5 °, and the end face of the quartz optical fiber was cut so as to be 7.5 °. FIG. 4 shows an outline of this connection state. In FIG. 2, reference numeral 1 denotes a tellurite glass optical fiber as a first fiber, and reference numeral 2 denotes a silica-based optical fiber as a second fiber. A first fiber holder 3a and a second fiber holder 3b having a mechanism for rotating these with respect to the optical axis of the optical fiber.
Respectively. The first fiber holder is rotated as indicated by an arrow 6 while observing with a CCD camera installed vertically above the optical fiber connection portion, and the plane including the optical axis and the vertical axis of the non-quartz optical fiber is aligned with the YZ plane. It was made parallel. Next, the second fiber holder was rotated as indicated by an arrow 6 ′ so that a plane including the optical axis and the vertical axis of the silica-based optical fiber was parallel to this plane. Thereby, the fiber end faces can be aligned at the time of connection.

Thereafter, the fiber end faces are brought close to each other so that the fiber end spacing is 5 μm and the end faces are parallel to each other, and the quartz fiber is rotated in the ZY plane about the center of the end face as the rotation center (arrow). 7). This is achieved by the rotation function of the second fiber holder 3b, which can move on a circumference centered on the fiber connection portion (the center between the arc discharge electrodes 4 and 4). However, the alignment of the fiber ends is performed by analyzing image information obtained from a CCD camera.

The distance between the fiber ends is further reduced, and the second fiber holder 3b is moved in parallel in the X-axis, Y-axis, and Z-axis directions within a plane parallel to the end face of the silica-based optical fiber, and the connection end face of the optical fiber is moved. The alignment was performed so that the optical axes coincided. However, this alignment was performed so that the semiconductor laser light having a wavelength of 1.2 μm incident from the quartz-based optical fiber side was detected by a photodiode coupled to a tellurite glass fiber, and the output was maximized.

Thereafter, the ends of the fibers are brought closer to each other and brought into contact with each other. Then, arc discharge is caused from the electrode 4 to heat the connection end face of the fibers, and a load in the optical axis direction is applied by a load cell provided in the first fiber holder 3a. While monitoring
The connection was made by applying pressure. However, it is possible to control the atmosphere in the connecting device by introducing a predetermined gas into the connecting portion from the gas inlet 5.

The loss after connection was less than 0.01 dB. When the return loss at the connection point at 1.3 μm was measured using a commercially available return loss measuring apparatus, the value measured from both the tellurite glass optical fiber side and the silica-based optical fiber side was found to be either value. In this case as well, it was below the measurement limit (60 dB) of the device. That is, it was shown that the present invention is also effective for connecting optical fibers having different connection end face angles effective for reducing the return loss.

In the same manner as in this embodiment, Zr-based fluoride glass optical fiber, In-based fluoride glass fiber optical fiber, and chalcogenide glass optical fiber were connected to fibers having different angles. Thus, a connection having a low loss and a return loss of 60 dB or less was realized.

(Embodiment 7) In Embodiment 6, the heating of the end face of the optical fiber was performed by using Yb incident from a silica-based optical fiber.
An optical fiber was connected in the same manner as in Example 6, except that the heating by the fiber laser was used. After the optical fiber was aligned in the same manner as in Example 6, the distance between the ends of the optical fiber was set to 1 μm.
m, and 1 W of laser light was incident from the quartz side. After about 5 seconds of incidence, the laser light was shut off. As a result, the end face of the tellurite glass optical fiber was melted and fused to the end face of the silica-based optical fiber, and both fibers were connected.

The connection loss was 0.01 dB, and the return loss was 60 dB or less. At this time, the same connection was possible as long as the laser used had an oscillation wavelength transmitting through the quartz optical fiber.

Example 8 A chalcogenide glass optical fiber was used as the first fiber, and the angle between the optical axis and the vertical axis of the fiber end face was 5.5 °. Also,
A quartz optical fiber was used as the second fiber, and the angle between the optical axis and the vertical axis was 8 °. Fiber holding and alignment were performed in the same manner as in Example 6. The heating of the fiber was performed by high frequency induction heating. However, as a susceptor for high-frequency induction heating, a Mo ring was installed so as to surround the fiber connection portion, and a coil was installed around the periphery. A pressing force of about 1 g is applied between the end face of the silica-based optical fiber and the end face of the chalcogenide optical fiber, a high-frequency voltage is applied to the coil, and the voltage applied when the load applied to the fiber starts to change due to the melting of the chalcogenide optical fiber. The application was stopped. At the same time, 0.1μ
By m, the optical axis method of the silica-based optical fiber was retracted.

The connection loss was 0.01 dB or less, and the return loss measured from the chalcogenide glass fiber side and from the silica-based optical fiber side were both 60 dB or less, which is the measurement limit of the apparatus. The same connection could be realized by using resistance heating using Kanthal wires instead of the high-frequency induction heating coil.

As the first fiber, a tellurite glass optical fiber is used instead of the chalcogenide optical fiber,
Similar connection characteristics could be realized by using a Zr-based fluoride glass optical fiber or an In-based glass optical fiber.

(Example 9) In the same manner as in Example 6, a tellurite glass optical fiber and a silica-based optical fiber were connected. Next, an ultraviolet-curable epoxy resin was applied to the connection portion between the tellurite glass optical fiber and the quartz-based optical fiber, and then cured using a UV lamp to form a 200 μm-thick epoxy resin layer at the optical fiber connection portion. . As a result, the connection portion was reinforced against atmospheric moisture and mechanical stress, and the tensile strength was improved to 210 MPa.

An epoxy resin layer similar to the above was formed at the connection portion of an optical fiber connected using a Zr-based fluoride glass optical fiber, an In-based fluoride glass optical fiber, or a chalcogenide glass optical fiber as the first fiber. As a result, it was confirmed that the present invention was effective for these, and in particular, when a fluoride glass optical fiber was used, the effect of suppressing the deterioration of the strength of the connection portion against moisture in the atmosphere could be confirmed. In addition, instead of using UV-curable epoxy resin as the resin applied to the connection part, UV-curable acrylic resin, silicone resin or any other polymer can be used to reinforce the connection part and protect it against moisture. The effect was confirmed.

(Embodiment 10) The same connection as in Embodiment 9 was made. However, after connecting the first fiber and the second fiber to two glass tubes each having the same inclination as the angle of the optical fiber connection end face to be connected and having an inner diameter larger than the optical fiber diameter, the connection is performed. After the connection, the connection portion of the fiber was fixed with a butt adhesive. Next, the other end face of the glass tube not fixed with the adhesive was fixed to the fiber with the adhesive. As a result, the connection portion was covered with the glass tube, and the connection portion could be protected against external impact.

The same effect was obtained by connecting another non-quartz fiber instead of the tellurite glass optical fiber as the first fiber.

The same effect could be obtained by using a tube made of a material such as ceramics or metal instead of the glass tube covering the connection portion.

By using the resin coating of the ninth embodiment in combination with the connecting portion protection member of the present embodiment, it is possible to obtain a protective effect against humidity as well as external impact.

[0075]

As described above in detail, according to the present invention, fusion splicing of optical fibers made of different glass materials, which has been difficult in the past, can be realized. As a result, a connection that does not use an adhesive can be realized, so that a highly reliable fiber connection can be achieved, and a process such as V-groove assembly or polishing is not required, so that a simple and low-loss connection is realized. There is also an advantage that it can be.

[Brief description of the drawings]

FIG. 1A is a diagram showing a propagation state of incident light in the case of connection in which an optical fiber connection interface is perpendicular to an optical axis, and FIG.
Is a diagram showing the propagation state of the incident light when the connection interface is inclined with respect to the optical axis, and (c) is a diagram showing the propagation state of the incident light when the connection satisfies Snell's law of the present invention. It is.

FIG. 2 is a conceptual diagram of the connection device of the present invention.

FIG. 3 is a conceptual diagram showing one embodiment of the fiber connection method of the present invention.

FIG. 4 is a conceptual diagram showing another embodiment of the fiber connection method of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 1st fiber 2 2nd fiber 3a 1st fiber holder 3b 2nd fiber holder 4 Electrode for arc discharge 5 Gas inlet 101 Incident light 102 Transmitted light 103 Reflected return light 104 Connection interface

Continuing on the front page (72) Inventor Jun Mori, Nippon Telegraph and Telephone Corporation 3-2-1, Nishi-Shinjuku, Shinjuku-ku, Tokyo (72) Inventor Hirotaka Ono 3-2-1, Nishi-Shinjuku, Shinjuku-ku, Tokyo Nippon Telegraph and Telephone Telephone Co., Ltd. (72) Inventor Toshiyuki Shimada 3-19-2 Nishishinjuku, Shinjuku-ku, Tokyo Japan Telegraph and Telephone Co., Ltd. (72) Inventor Yoshiki Nishida 3-192-2, Nishishinjuku, Shinjuku-ku, Tokyo Japan Telegraph and Telephone Co., Ltd. (72) Inventor Yasutake Oishi 3-19-2 Nishi-Shinjuku, Shinjuku-ku, Tokyo Japan Telegraph and Telephone Co., Ltd.

Claims (18)

[Claims] 1. A method for connecting two optical fibers, at least one of which is a non-silica-based optical fiber, comprising the steps of:
In a state where the optical axis of the second fiber and the optical axis of the second fiber made of a different glass are aligned so that they coincide with each other at the connection end face.
At least the first of the connection end portions of the two optical fibers.
And fusing the two optical fibers by heating or softening or melting the connection end of the first fiber. 2. The optical fiber connection method according to claim 1, wherein the two optical fibers are fusion-spliced in a state where the connection end portion of the second fiber is not softened or melted. 3. The light according to claim 1, wherein a heating temperature of a connection end portion of the optical fiber is equal to or higher than a lowest glass transition temperature of glass constituting the non-quartz optical fiber. Fiber connection method. 4. The non-quartz optical fiber is made of one selected from the group consisting of tellurite glass fiber, Zr-based fluoride glass fiber, In-based fluoride glass fiber, and chalcogenide glass fiber. Item 4. The method for connecting an optical fiber according to any one of Items 1 to 3. 5. The connection end face of the optical axis of the first fiber, wherein the optical axis of the first fiber and the optical axis of the second fiber are inclined at different angles with respect to the vertical axis of the connection end face. The relationship between the inclination angle θ ₁ of the second fiber with respect to the vertical axis and the inclination angle θ ₂ of the connection end face of the optical axis of the second fiber with respect to the vertical axis is represented by n ₁ for the core refractive index of the _first fiber, When the ratio is n ₂ , the connection is made so as to satisfy the Snell's law of (sin θ ₁ ) / (sin θ ₂ ) = n ₂ / n ₁ within a range of ± 10%. The method for connecting an optical fiber according to claim 1. 6. The optical fiber connection method according to claim 1, wherein the connection end portion of the optical fiber is heated by arc discharge. 7. The optical fiber according to claim 1, wherein the connection end portion of the optical fiber is heated by incidence of a laser beam.
6. The method of connecting an optical fiber according to any one of claims 1 to 5, 8. The method for connecting optical fibers according to claim 7, wherein the laser beam is incident by a carbon dioxide gas laser. 9. The optical fiber connection method according to claim 1, wherein the connection end portion of the optical fiber is heated by high-frequency induction heating. 10. The light according to claim 1, wherein heating of the connection end portion of the optical fiber is performed by energizing heating of a resistor disposed near the optical fiber connection end portion. Fiber connection method. 11. The distance between the ends of the optical fibers when the ends of the optical fibers are heated after the alignment of the first fiber and the second fiber is 0 to 10 μm. Item 11. The method for connecting an optical fiber according to any one of Items 1 to 10. 12. When the distance between the ends of the optical fibers is zero, a pressing force of 10 g or less is applied between the ends of the optical fibers in the axial direction of the optical fibers.
The method for connecting an optical fiber according to the above. 13. After aligning the first fiber and the second fiber, at least the connection end portion of the first fiber among the connection end portions of the two optical fibers is heated or heated. 13. The method of connecting an optical fiber according to claim 1, further comprising changing a distance between the optical fibers. 14. A periphery of a connection portion between the first fiber and the second fiber is at least selected from the group consisting of glass, an inorganic crystal material, a polymer material, and a metal along an optical axis of the optical fiber. 14. The method of connecting an optical fiber according to claim 1, wherein the optical fiber is reinforced by a member made of one material. 15. An apparatus for connecting a first fiber, which is a non-silica-based optical fiber, to a second fiber made of glass different from the first fiber, wherein the gas introduction means, the first fiber and the second fiber are connected to each other. Means for aligning the optical axes of the second fiber and the second fiber so as to coincide with each other at the connection end face, and means for heating at least a connection end portion of the first fiber of the first fiber and the second fiber. An optical fiber connection device, comprising: 16. The alignment means includes a plane including an optical axis of a first fiber and a vertical axis of a connection end face of the first fiber, an optical axis of a second fiber, and the second fiber. So that a plane including the vertical axis of the connection end face of
A rotation mechanism for rotating a first fiber holder for fixing the second fiber and a second fiber holder for fixing the second fiber, and a movement mechanism for three-dimensionally translating the second fiber holder, and A rotation mechanism for rotating one of the optical fibers in a plane around the center of the optical fiber end face as a center of rotation is provided to make the connection end face of the first fiber and the connection end face of the second fiber parallel. The optical fiber connection device according to claim 15, wherein: 17. The gas introduction means has a gas introduction port, and the gas introduction port is used to maintain a portion where the ends of the first fiber and the second fiber are installed in a predetermined atmosphere. The optical fiber connection device according to claim 15 or 16, wherein a drying gas is introduced from the device. 18. The optical fiber connection device according to claim 15, further comprising a detection mechanism for detecting a weight applied to the optical fiber on at least one of the fiber holders for fixing the optical fiber. The optical fiber connection device according to any one of the above.