JP2015040916A - Optical fiber lateral input and output device and optical fiber lateral input and output method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical fiber lateral input and output device and an optical fiber lateral input and output method capable of efficiently collecting an optical signal and efficiently inputting the optical signal to the other optical fiber, easily collecting the optical signal into one optical system, and preventing a stray light.SOLUTION: An input and output device 10 includes: a fixing jig 30 having a curved surface part 31 and a plane part 33 arranged at both ends of the curved surface 31; and an abutment part 40 abutting against a midway part 21 from an opposite side of the curved surface part 31 so as to sandwich the midway part 21 which is a portion of an optical fiber 20 together with the curved surface part 31 and forming a bending part 23 on the midway part 21 together with the curved surface part 31 by the abutment. The input and output device 10 is arranged on the fixing jig 30 and has an input and output optical system 50 for inputting and outputting an optical signal so that the optical signal is input to and output from the optical fiber 20 from a lateral side. When the optical signal is input to and output from the optical fiber 20 from the lateral side, the abutment part 40 and the curved surface part 31 form the bending part 23 so that the optical signal is input to and output from a linear part 25.

Description

  The present invention relates to an optical fiber side input / output device and an optical fiber side input / output method for inputting / outputting an optical signal to / from an optical fiber from the side of the optical fiber.

The side input / output technology is a technology that enables, for example, an optical signal to be input to or output from an optical fiber from the side of the optical fiber. In order to implement this technique, it is necessary to relax the total reflection condition in the optical fiber and to provide the optical fiber with a bent portion for inputting and outputting optical signals. For this reason, the optical fiber is temporarily bent. Such a technique is disclosed in Patent Document 1 and Non-Patent Document 1, for example.
In the side input / output technology, the coated optical fiber 101 is bent by a cylindrical portion 103 as shown in FIG. 9A. The optical signal is input / output from the bending portion 105 to the outside. As shown in FIG. 9A, for example, the output optical signal is acquired by the lens-attached fiber 109 or the like via the refractive index matching agent 107.

As usage applications of this technology, for example, the following three types of leakage light monitor, test light input tool, and short break switch have been proposed.
Application 1 / Leakage light monitor: The bending condition of the bent portion is adjusted so that the insertion loss of the optical signal from the optical fiber with cover to the optical fiber with lens is maintained, for example, without affecting communication. The leakage light monitor acquires an optical signal output from the bent portion to the outside through the optical fiber with a lens, and monitors the signal in the optical signal.
Application 2 / Test light input tool: Optical coupling efficiency in the traveling direction of the optical signal shown in Application 1 and the traveling direction of the optical signal opposite to that in Application 1 (the optical signal travels from the optical fiber with lens to the optical fiber with cover) The optical coupling efficiencies in FIG. 4 are equal to each other when the input and output fiber diameters are the same. Therefore, in the test light input tool, the bending condition of the bending portion is adjusted so that the insertion loss of the optical signal from the optical fiber with a lens to the optical fiber with a cover is maintained, for example, without affecting communication. The test light input tool inputs an optical signal from the outside through an optical fiber with a lens.
Application 3-Short interruption switch: The short interruption switch switches light paths by switching light paths while optical signals are input and output at the bent part.
Applications 1 to 3 are disclosed in Non-Patent Document 2 to Non-Patent Document 4, for example.

Next, with reference to FIG. 9B, a phenomenon in which an optical signal is output from the bent portion 223 to the outside will be described geometrically. An example will be described in which the bending radius of the bent portion 223 is approximately 2.5 mm, for example, and the bending angle of the optical fiber 200 is approximately 150 degrees, for example.
In the bent portion 223, a part of the optical signal propagating through the core 200a is input to the cladding layer 200b at an angle less than the critical angle determined by the difference between the refractive index of the core 200a and the refractive index of the cladding layer 200b. Next, the optical signal is output from the cladding layer 200b and input to the coating layer 200c covering the cladding layer 200b. The optical signal reaches the outermost layer of the coating layer 200c. When the outside is air, the optical signal is totally reflected at the interface between the outermost layer and air. However, when the external environment is, for example, a refractive index matching agent or glass having a refractive index of about 1.5, an optical signal is output from the outermost layer to the outside. This optical signal output to the outside is referred to as primary output light.

  In addition, an optical signal that is not less than the critical angle at the interface between the core 200a and the clad layer 200b and is totally reflected and does not reach the clad layer 200b propagates through the core 200a while being totally reflected. The optical signals are successively input to the clad layer 200b when the bending portion 223 becomes less than the critical angle. As described above, this optical signal is output from the outermost layer to the outside. This optical signal output to the outside is referred to as secondary output light. Hereinafter, similarly, the optical signal output to the outside is referred to as tertiary output light and quaternary output light.

  The intensity of the optical signal output to the outside is maximum in the primary output light, decreases in the secondary output light, decreases further in the tertiary output light, and decreases further in the quaternary output light. To decrease. This phenomenon hardly depends on the thickness of the coating layer 200c as long as the refractive index of the coating layer 200c is approximately the same as the refractive index of the refractive index matching agent.

JP 2009-25210 A

Tanaka, Araki, Higashi, "Individual test of PON branch line by local injection", 2008 IEICE General Conference B-10-5, Proceedings of Communication Lecture 2, PP288, 2008-3 Honda, Iwata, Shinho, Kawano, Manabe, Higashi, “Study on optical fiber breakage in small-diameter bending test”, 2012 IEICE Communication Society B-10-23, Communication Lectures Collection 2, P205 Iwata, Nado, Honda, Manabe, Higashi, “Design examination of test light incidence mechanism using optical fiber lateral input technology”, The Institute of Electronics, Information and Communication Engineers, IEICE Technical, OFT2011-84, OPE2011-210, pp . 57-60, 2012-3-2 Shinbo, Iwata, Honda, Kawano, Manabe, Higashi, “Basic study on the input part of the core contrast device using local optical input technology” The Institute of Electronics, Information and Communication Engineers, Institute of Science

As shown in FIG. 9B, the optical signal is output a plurality of times as primary output light, secondary output light, tertiary output light, and quaternary output light. It is not easy to collect all these optical signals efficiently and input them efficiently to other optical fibers 200.
In the optical signal output from the bending portion 223, the secondary output light, the tertiary output light, and the quaternary output light, which are output lights other than the primary output light, are output separately from the primary output light. . That is, the divergence angle of the entire output light is increased. For this reason, it is difficult to condense the primary output light and the output light other than the primary output light on one input optical system.
Further, the output light other than the primary output light becomes leaky light, which becomes wasted light or stray light.

  The present invention has been made in view of these circumstances, can efficiently collect an optical signal, can efficiently input an optical signal to another optical fiber, can be easily condensed on one optical system, and stray light. It is an object of the present invention to provide an optical fiber side input / output device and an optical fiber side input / output method.

  In order to achieve the object, the present invention provides an optical fiber side input / output device for inputting / outputting an optical signal to / from the optical fiber from the side of the optical fiber, wherein a bent portion is provided in the middle portion of the linear optical fiber. A curved surface portion on which the midway portion is placed for forming; and a flat portion disposed on both ends of the curved surface portion on which the midway portion is placed to form a straight portion on the midway portion. A fixing jig and abutting portion that strikes the midway portion from the opposite side of the curved surface portion so as to sandwich the midway portion together with the curved surface portion, and forms a bent portion in the midway portion together with the curved surface portion by abutment, An input / output optical system that inputs and outputs the optical signal so that the optical signal is input to and output from the side to the optical fiber. Input / output to the optical fiber from the side As the optical signal is output from the linear portion, wherein the abutment portion and the curved portion to provide an optical fiber side input and output device, characterized in that to form the bent portion.

  In order to achieve the object, the present invention provides an optical fiber side input / output method for inputting / outputting an optical signal to / from the optical fiber from the side of the optical fiber. A curved surface portion on which the midway portion is placed in order to form a bent portion, and a linear portion on the midway portion where the midway portion is placed and disposed at both ends of the curved surface portion. The abutting portion is abutted against the midway portion from the opposite side of the curved surface portion so as to sandwich the midway portion together with the curved surface portion, and by the abutting portion and the curved surface portion by abutment. A bent portion is formed in the middle portion, an input / output optical system is disposed in the fixing jig, and the optical signal is input / output to / from the optical fiber from the side. Input / output optical signal, the optical signal from the side The abutting portion and the curved surface portion form the bent portion so that the optical signal is input / output from the straight portion when input / output to / from the optical fiber. Provide input / output methods.

  According to the present invention, an optical fiber side input / output device capable of efficiently condensing an optical signal, efficiently inputting the optical signal to another optical fiber, easily condensing into one optical system, and preventing stray light. And an optical fiber side input / output method.

FIG. 1A is a schematic diagram of an optical fiber side input / output device according to a first embodiment of the present invention, and is a diagram showing that an optical signal is output. FIG. 1B is a diagram illustrating that an optical signal is input. FIG. 2A is a diagram illustrating a state in which an optical signal is output from a bent portion according to a condition A, and illustrates that light other than the primary output light is also output. FIG. 2B shows a state in which the optical signal is output from the straight line portion under the condition B, and shows that only the primary output light is output. FIG. 2C is a diagram illustrating a ratio of an optical signal propagating through an optical fiber and a ratio of an optical signal output to the side as primary output light under various conditions. FIG. 2D is a diagram summarizing the results of outputting the primary output light. FIG. 3 is a schematic diagram of an optical fiber side input / output device according to the second embodiment. FIG. 4 is a schematic diagram of an optical fiber side input / output device according to the third embodiment. FIG. 5 is a schematic diagram of an optical fiber side input / output device according to the fourth embodiment. FIG. 6 is a schematic diagram of an optical fiber side input / output device according to the fifth embodiment. FIG. 7 is a schematic diagram of an optical fiber side input / output device according to the sixth embodiment. FIG. 8 is a schematic diagram of an optical communication line switching device having an optical fiber side input / output device according to the seventh embodiment. FIG. 9A is a diagram for explaining a general side input / output technique. FIG. 9B is a diagram for geometrically optically explaining a phenomenon in which an optical signal is output to the outside from a bending portion.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Note that in some drawings, a part of the members is omitted for clarity of illustration.
[First Embodiment]
[Constitution]
The first embodiment will be described with reference to FIGS. 1A, 1B, 2A, 2B, 2C, and 2D.

[Optical fiber side input / output device]
As shown in FIG. 1A and FIG. 1B, an optical fiber side input / output device (hereinafter, input / output device 10) inputs / outputs an optical signal to / from the optical fiber 20 from the side of the optical fiber 20.

[Configuration of Input / Output Device 10]
As shown in FIGS. 1A and 1B, the input / output device 10 includes a fixed jig 30 having a curved surface portion 31 and flat portions 33 disposed at both ends of the curved surface portion 31, and the optical fiber 20 together with the curved surface portion 31. Abutting portion 40 that strikes the middle portion 21 from the opposite side to the curved surface portion 31 so as to sandwich the middle portion 21 that is a part of the middle portion 21 and forms a bent portion 23 in the middle portion 21 together with the curved surface portion 31 by the abutment. ing. The input / output device 10 further includes an input / output optical system 50 that is disposed in the fixing jig 30 and inputs / outputs an optical signal so that the optical signal is input / output to / from the optical fiber 20 from the side.

[Fixing jig 30]
The fixing jig 30 including the curved surface portion 31 and the flat surface portion 33 can transmit the optical signal output from the optical fiber 20 as shown in FIG. 1A, and further input the optical signal into the optical fiber 20 as shown in FIG. 1B. Thus, it is formed of a permeable member. Such a member has a transparent member such as glass or acrylic.

  As shown in FIGS. 1A and 1B, the flat portion 33 is disposed at both ends of the curved surface portion 31 in the axial direction of the optical fiber 20, and is connected to the curved surface portion 31. The flat surface portion 33 is disposed on the same plane as the curved surface portion 31. The curved surface portion 31 is bent toward the abutting portion 40. For this reason, one flat surface portion 33a is inclined so as to rise with respect to the other flat surface portion 33b.

As shown in FIG. 1A and FIG. 1B, the curved surface portion 31 is disposed to form a bent portion 23 in the midway portion 21 of the linear optical fiber 20, and the midway portion 21 is placed on the curved surface portion 31. Placed. The curved surface portion 31 can come into contact with the abutting portion 40 in a state where the midway portion 21 is not placed.
As shown in FIGS. 1A and 1B, the midway portion 21 is placed on the flat surface portion 33. The flat surface portion 33 is disposed to form the straight portion 25 in the midway portion 21.
The midway portion 21 is placed on the curved surface portion 31 and the flat surface portion 33 at the same time.

[Abutting part 40]
As shown in FIGS. 1A and 1B, the abutting portion 40 has a curved surface portion 41 that sandwiches the midway portion 21 together with the curved surface portion 31. The abutting portion 40 has, for example, a cylindrical portion, and the curved surface portion 41 is disposed on a part of the circumferential surface of the cylindrical portion.

As shown in FIG. 1A, the curved surface portion 41 and the curved surface portion 31 function as a sandwiching portion that sandwiches the midway portion 21 from a direction orthogonal to the axial direction of the optical fiber 20, in other words, from the side of the midway portion 21. The curved surface portion 41 presses the midway portion 21 toward the curved surface portion 31, for example, causes the midway portion 21 to follow the bending condition of the curved surface portion 31.
The bending condition of the curved surface portion 31 and the bending condition of the curved surface portion 41 correspond to the bending condition of the bending portion 23 and are the same as each other.

[Input / output of optical signal]
As shown in FIGS. 1A and 1B, in this embodiment, the input / output of the optical signal is shifted from the bent portion 23 to the straight portion 25, and the optical signal is input / output from the straight portion 25. For this reason, in this embodiment, when the optical signal is input / output to / from the optical fiber 20 from the side, the abutting portion 40 and the curved surface portion 31 are the bent portion 23 so that the optical signal is input / output from the straight portion 25. Form. These conditions are summarized below.

[Conditions for optical signal to be output from linear portion 25]
The results of tracking and observing the optical signal output from the optical fiber 20 while changing the curvature radius of the bending portion 23 and the bending angle of the optical fiber 20 are summarized below.
Whatever the radius of curvature and the bending angle, the optical signal output from the optical fiber 20 (hereinafter referred to as output light) is observed at a position approximately 5 mm from the bending start position of the bending portion 23, for example. To do.

As an example, the conditions are set as follows, for example.
Condition A: As shown in FIG. 2A, the bending radius of the bent portion 23 is approximately 2.5 mm, and the bending angle of the optical fiber 20 is approximately 150 degrees.
Condition B: As shown in FIG. 2B, the bending radius of the bent portion 23 is approximately 2.5 mm, and the bending angle of the optical fiber 20 is approximately 170 degrees.
The bending angle of condition B shown in FIG. 2B is larger than the bending angle of condition A shown in FIG. 2A. For this reason, the bent portion 23 in the condition B is steeper than the bent portion 23 in the condition B, and the length of the bent portion 23 in the condition B is shorter than the length of the bent portion 23 in the condition A.

  The result of tracking and observing the output light under the condition A shown in FIG. 2A is as follows. For example, approximately 38% of the optical signal propagating through the optical fiber 20 is output to the side as primary output light, and approximately 19% of the optical signal propagating through the optical fiber 20 is output light other than the primary output light (for example, Secondary output light, tertiary output light, and fourth output light) are output to the side, and approximately 43% of the optical signal propagating through the optical fiber 20 propagates through the optical fiber 20. Under condition A, approximately 57% of the optical signal is output as output light. These output lights are output from the bending portion 23.

  The result of tracking and observing the optical signal under the condition B shown in FIG. 2B is as follows. For example, approximately 38% of the optical signal propagating through the optical fiber 20 is output to the side as primary output light, and approximately 62% of the optical signal propagating through the optical fiber 20 propagates through the optical fiber 20. In addition, the optical signal output to the side as output light other than the primary output light was not observed. Therefore, under condition A, approximately 38% of the optical signal is output as output light. These output lights are output from the straight line portion 25.

  In the conditions A and B, regardless of the bending angle, the ratio of the primary output light in the optical signal (in other words, the intensity of light in a specific direction) is substantially the same as 38%.

Under condition A, it was found that the optical signal was output from the bending portion 23, the optical signal was output a plurality of times, and the divergence angle of the entire output light was found to be large.
That is, if the bending angle is small as in condition A, the optical signal is output from the bending portion 23 and the optical signal is output in a plurality of times, so that it becomes difficult to efficiently collect all of the output light. It becomes difficult to efficiently input light into another optical fiber 20. Further, since the divergence angle of the entire output light is increased, it is difficult to collect the primary output light and the output light other than the primary output light on one input / output optical system 50. Further, output light other than the primary output light (approximately 19% of the optical signal) becomes leaky light, which becomes useless light and stray light.

On the other hand, in condition B, it can be seen that the optical signal is output from the linear portion 25, the optical signal is output only once, and the divergence angle of the entire output light, that is, the primary output light is small. all right.
In other words, if the bending angle is large as in condition B, the optical signal is output from the linear portion 25 and the optical signal is output only once to the side, so that all of the output light can be efficiently and easily collected. Can be efficiently and easily input to the other optical fiber 20. Further, since the optical signal is output only once and the divergence angle of the entire output light becomes small, it can be easily condensed on one input / output optical system 50. Moreover, generation of output light other than the primary output light can be suppressed, optical signals can be prevented from being output unnecessarily, and stray light can be prevented.

  Therefore, the radius of curvature is approximately 1.7 mm, approximately 2.0 mm, approximately 2.5 mm, approximately 4 mm, and the bending angle is approximately 170 degrees, approximately 165 degrees, approximately 160 degrees, approximately 150 degrees, and approximately 90 degrees. The ratio A1 (%) of the optical signal output to the side as the primary output light and the ratio B1 (%) of the optical signal propagating through the optical fiber 20 under these conditions are summarized in FIG. 2C.

  If the bending angle is the same at the ratio A1, the smaller the radius of curvature, the higher the ratio, that is, most of the optical signal is output to the side. If the radius of curvature is the same, the smaller the bending angle, the higher the ratio, that is, most of the optical signal is output to the side.

  In the ratio B1, if the bending angle is the same, the larger the radius of curvature, the higher the ratio, that is, most of the optical signal propagates. If the radius of curvature is the same, the larger the bending angle, the higher the ratio, that is, most of the optical signal propagates.

Based on this result, the result of outputting the optical signal from the linear portion 25 is summarized in FIG. 2D. The optical signal is primarily output from the linear portion 25 under the condition that the radius of curvature is approximately 2.5 mm or less, the bending angle is 165 degrees or more and approximately 170 degrees or less, and when the curvature radius is 4 mm, the condition is 170 degrees. It turns out that it is output as light. Preferably, the optical signal is transmitted under a condition where the radius of curvature is approximately 1.7 mm or greater and approximately 2.5 mm or less, the bending angle is approximately 165 degrees or greater and approximately 170 degrees or less, and when the radius of curvature is 4 mm, the condition is 170 degrees. It was found that the light was output from the linear portion 25 as primary output light. It was found that the remainder was output from the bent portion 23.
Although an example in which an optical signal is output has been described above, the same applies to the case where an optical signal is input as shown in FIG. 1B.

  Since the optical signal is input / output from the straight line portion 25 in this way, the radius of curvature of the bent portion 23 is approximately 1.7 mm or more and approximately 2.5 mm or less, and the bending angle of the optical fiber 20 is approximately 165 degrees or more and approximately 170 degrees. The abutting portion 40 and the curved surface portion 31 form a bent portion 23 so as to be as follows.

  Under the maximum conditions in which the optical signal is output from the linear portion 25, the radius of curvature is 2.5 mm, the bending angle is 170 degrees, the size on the screen is 0.15 mm (FWHM), and the divergence angle is 2.2 degrees (NA). = 0.02) (FWHM). This can be sufficiently coupled to the optical fiber 20 having a numerical aperture of 0.1 using a lens having a diameter of 0.25 mm, for example. This is also true for the conditions output from the straight line portion 25 at a bending angle of 170 degrees, a curvature radius of 1.7 mm to 4.0 mm, a bending angle of 165 degrees and a curvature radius of 1.7 mm to 2.5 mm. .

[Input / output optical system 50]
As shown in FIGS. 1A and 1B, the input / output optical system 50 is disposed at least at one end portion of the fixing jig 30 in the axial direction of the optical fiber 20. As shown in FIG. 1A, the input / output optical system 50 receives an optical signal that is output from the linear portion 25 of the optical fiber 20 to the side and transmitted through the fixing jig 30 as shown in FIG. 1B. The input / output optical system 50 outputs an optical signal so as to pass through the fixing jig 30 and to be input to the optical fiber 20 from the side via the linear portion 25.

[Action]
As shown in FIG. 1A, for example, an optical signal is output from the straight line portion 25 to the side of the optical fiber 20. In this case, the optical signal is output only once, in other words, only the primary output light is output. The optical signal passes through the fixing jig 30 and is input to the input / output optical system 50.

[effect]
As described above, in this embodiment, since the optical signal is input / output from the linear portion 25, the bending radius of the bending portion 23 is approximately 1.7 mm or more and approximately 2.5 mm or less, and the bending angle of the optical fiber 20 is approximately. The abutting portion 40 and the curved surface portion 31 form a bent portion 23 so that the angle is 165 degrees or more and substantially 170 degrees or less. In other words, in this embodiment, the input / output position of the optical signal is shifted from the bent portion 23 to the straight portion 25.
Thereby, in this embodiment, an optical signal can be output from the linear part 25, an optical signal can be output only once, and the divergence angle of the whole output light, ie, primary output light, can be made small.
Therefore, in the present embodiment, all the output light can be collected efficiently and easily, and the output light can be efficiently and easily input to the other optical fibers 20. In the present embodiment, light can be easily collected on one input / output optical system 50, and stray light can be prevented. Although an example in which an optical signal is output has been described above, the same applies to the case where an optical signal is input as shown in FIG. 1B. In the present embodiment, the optical coupling efficiency at the input can be made comparable to the optical coupling efficiency at the output.

  In the present embodiment, it is not necessary to polish both the curved surface portion 31 and the flat surface portion 33, and only the flat surface portion 33 that forms the linear portion 25 needs to be polished, so that the processing cost can be reduced.

  Moreover, in this embodiment, the abutting part 40 which has a cylindrical part can be manufactured easily and cheaply.

Unlike the present embodiment, when the optical signal is output from the bending portion 23 to the outside, the intensity of the optical signal output to the outside is weak, and the optical coupling efficiency between the coated fiber and the lensed fiber is low. An optical signal is not input to the input / output optical system 50 disposed outside, causing an input error.
However, in the present embodiment, since the optical signal is output from the straight line portion 25 and the optical signal is output to the side only once, all the output light can be efficiently and easily collected, and the output light can be collected by another optical fiber 20. Can be input efficiently and easily. Therefore, in this embodiment, an optical signal can be reliably input to the input / output optical system 50, and an input error can be prevented.

Unlike the present embodiment, when an optical signal is input to the bending portion 23 from the outside, if the optical coupling efficiency is low, the optical signal needs to be amplified by an optical amplifier or the like. It becomes expensive.
However, in the present embodiment, since the optical signal is output from the straight line portion 25 and the optical signal is output to the side only once, all the output light can be efficiently and easily collected, and the output light can be collected by another optical fiber 20. Can be input efficiently and easily. This also applies to input. Therefore, in this embodiment, an optical amplifier or the like can be omitted, and the input / output device 10 can be prevented from becoming expensive.

Note that the total amount of optical signals output to the outside increases as the radius of curvature of the bent portion 23 decreases and as the bending angle of the optical fiber 20 increases rapidly. This is generally known as disclosed in Non-Patent Document 1 to Non-Patent Document 4.
However, simply decreasing the radius of curvature and increasing the bending angle has the following drawbacks.
Disadvantage 1: Insertion loss may reach a level that affects communication.
Disadvantage 2: As the radius of curvature decreases, the probability that the optical fiber 20 will break increases. For example, in Non-Patent Document 2, the radius of curvature is 1.7 mm.
Disadvantage 3: The divergence angle of the output optical signal increases as the bending angle of the optical fiber 20 increases. This leads to a decrease in light collection efficiency.
However, in the present embodiment, the bending radius of the bending portion 23 is approximately 1.7 mm or more and approximately 2.5 mm or less, and the bending angle of the optical fiber 20 is approximately 165 degrees or more and approximately 170 degrees or less. Can be prevented.

In addition, for example, in the maintenance of an optical communication line, it is desirable to minimize the loss of the optical signal when monitoring the optical signal. The secondary output light, the tertiary output light, and the quaternary output light, which are lights other than the primary output light as described above, are leakage lights, and are useless lights that are not used for communication and not used for a monitor. There is stray light. This light is delayed by another path having a different optical path length and input to the monitor, which adversely affects the monitor signal.
However, in this embodiment, the bending portion 23 is formed so that the bending radius of the bending portion 23 is approximately 1.7 mm or more and approximately 2.5 mm or less, and the bending angle of the optical fiber 20 is approximately 165 degrees or more and approximately 170 degrees or less. Thus, the optical signal can be output to the side only once, generation of output light other than the primary output light can be suppressed, the optical signal can be prevented from being output unnecessarily, and stray light can be prevented. Therefore, in this embodiment, it is possible to prevent the optical signal from adversely affecting the monitor signal during maintenance of the optical communication line.

In general, the larger the size of the output optical signal, the smaller the optical signal cannot be collected by, for example, a lens. Further, if the divergence angle of the primary output light is wide, for example, it is limited by the numerical aperture (about 0.1) of the optical fiber 20 on the light receiving side, so that loss occurs in optical coupling to the core of the optical fiber 20 on the light receiving side. . For this reason, it is known that only a part of the optical signal output to the outside can be acquired, and the acquisition of the optical signal becomes inefficient. When the optical signal is output from the bending portion 23, the divergence angle of the optical signal is widened due to the curved surface of the bending portion 23, and the light collection efficiency is reduced.
However, in the present embodiment, the optical signal can be output from the linear portion 25, the optical signal can be output only once, and the divergence angle of the entire output light, that is, the primary output light can be reduced. Therefore, in this embodiment, the size of the optical signal to be output is prevented from increasing, and the optical signal can be easily condensed small by, for example, a lens. Further, in the present embodiment, it is possible to prevent the optical signal acquisition from becoming inefficient. Moreover, in this embodiment, it can prevent that condensing efficiency falls.

[Second Embodiment / FIG. 3]
Only the points different from the above-described embodiment will be described below.
In the first embodiment, the entire fixing jig 30 is formed of a member capable of transmitting an optical signal, but it is not necessary to be limited to this.

  As shown in FIG. 3, the fixing jig 30 of the present embodiment includes a first member 30a having one flat surface portion 33a, and a second member 30b having a curved surface portion 31 and the other flat surface portion 33b. doing. The first member 30a is separate from the second member 30b. The first member 30 a is adjacent to the second member 30 b so that the first member 30 a is disposed on the same plane as the curved surface portion 31, and the first member 30 a is continuous with the curved surface portion 31. . The first member 30 a is in contact with the input / output optical system 50.

The first member 30 a is formed of, for example, a member that can transmit an optical signal output from the optical fiber 20 and further transmit an optical signal so that the optical signal is input to the optical fiber 20. Such a member has a transparent member such as glass or acrylic.
As described above, the first member 30a, which is a part of the fixing jig 30 interposed between the input / output optical system 50 and the flat portion 33 in contact with the linear portion 25 of the optical fiber 20 through which the optical signal is input and output, is the optical signal. It suffices to have a transmissive member that transmits light.

  The second member 30b is made of, for example, metal. The second member 30b is impermeable.

As described above, in this embodiment, the abutting portion 40 abuts and the second member 30b including the curved surface portion 31 that receives pressure from the abutting portion 40 is formed of metal. Therefore, in this embodiment, in the curved surface portion 31 formed of metal, the repeated durability can be improved as compared with the case where the curved surface portion 31 is formed of glass or acrylic. The accompanying reduction in coupling loss can be prevented. Further, in the present embodiment, processing the curved surface portion 31 on the second member 30b made of metal can be performed more easily than processing the curved surface portion 31 on the first member 30a such as glass or acrylic. In the present embodiment, since the second member 30b is made of metal, the curved surface portion 31 can also be polished. Therefore, in this embodiment, it can be made inexpensive.
Moreover, in this embodiment, since only the flat part 33a needs to be polished, the flat part 33a can be quickly and inexpensively polished.

[Third Embodiment / FIG. 4]
Only differences from the above-described embodiments will be described below.
As shown in FIG. 4, the fixing jig 30 of this embodiment is substantially the same as the fixing jig 30 of 2nd Embodiment, for example.
The curved surface portion 41 of the present embodiment sandwiches the midway portion 21 together with the curved surface portion 31 disposed on the second member 30b.

  As shown in FIG. 4, the abutment portion 40 of the present embodiment includes a first portion that sandwiches the midway portion 21 together with the flat portion 33 b disposed on the second member 30 b of the fixing jig 30 in order to form the straight portion 25. 1 plane portion 43a. The first flat portion 43 a is connected to one end of the curved surface portion 41 in the axial direction of the optical fiber 20.

  The abutting portion 40 has an application flat surface portion 45 that is disposed on, for example, the upper surface of the abutting portion 40 and directly applies a pressing force that presses the abutting portion 40 against the fixing jig 30. The pressing force is applied to a substantially central portion of the application plane portion 45.

  In the present embodiment, the midway portion 21 can be sandwiched by the curved surface portion 31 and the flat surface portion 33b of the fixing jig 30, and the curved surface portion 41 and the first flat surface portion 43a of the abutting portion 40 without being displaced. In the present embodiment, the optical fiber 20 is accurately and easily controlled to a desired shape by the curved surface portion 31 and the flat surface portion 33b of the fixing jig 30, and the curved surface portion 41 and the first flat surface portion 43a of the abutting portion 40. it can. In the present embodiment, the pressing force can be applied to the abutting portion 40 by the application flat surface portion 45 without waste.

[Fourth Embodiment / FIG. 5]
Only differences from the above-described embodiments will be described below.
As shown in FIG. 5, the fixing jig 30 of this embodiment is substantially the same as the fixing jig 30 of 2nd Embodiment, for example.

  As shown in FIG. 5, the abutting portion 40 of the present embodiment includes a first portion 30 that sandwiches the midway portion 21 together with the flat portion 33 a disposed on the first member 30 a of the fixing jig 30 to form the straight portion 25. It further has two plane portions 43b. The second flat surface portion 43 b is connected to the other end portion of the curved surface portion 41 in the axial direction of the optical fiber 20. Therefore, the curved surface portion 41 is sandwiched between the first flat surface portion 43a and the second flat surface portion 43b.

  Considering the third embodiment and the fourth embodiment, the abutting portion 40 is disposed on at least one of both ends of the curved surface portion 41, and the flat portion 33 a of the fixing jig 30 to form the straight portion 25. What is necessary is just to further have the plane parts 43a and 43b which pinch | interpose the midway part 21 with 33b.

  In the present embodiment, the midway portion 21 is displaced by the curved surface portion 31 and the flat surface portions 33a and 33b of the fixing jig 30, and the curved surface portion 41, the first flat surface portion 43a, and the second flat surface portion 43b of the abutting portion 40. And can be pinched more reliably. In the present embodiment, the optical fiber 20 is formed by the curved surface portion 31 and the flat surface portions 33a and 33b of the fixing jig 30, and the curved surface portion 41, the first flat surface portion 43a, and the second flat surface portion 43b of the abutting portion 40. It can be controlled accurately and more easily by the desired shape.

[Fifth Embodiment / FIG. 6]
Only differences from the above-described embodiments will be described below.
Usually, the short interruption switch is required to have a function of blocking light signals while light is input and output at the bending portion 23.
It can be seen that the condition that the ratio B1 of the optical signal propagating through the optical fiber 20 shown in FIG. 2D is reduced is that the radius of curvature is approximately 1.7 mm and the bending angle is approximately 90 degrees or more.

Therefore, as shown in FIG. 6, in the present embodiment, for example, two bending portions 23 are provided. One bent portion 23 bends gently, and an optical signal is input / output from the straight portion 25. The other bent portion 23 bends approximately 90 degrees or more, and the optical signal is blocked. One bent portion 23 is disposed at a position different from the other bent portion 23 in the axial direction of the optical fiber 20.
For this reason, two curved surface portions 31 are disposed, and one curved surface portion 31 is disposed at a position different from the other curved surface portion 31 in the axial direction of the optical fiber 20.
Two cylindrical abutting portions 40 are disposed, and one abutting portion 40 is disposed at a position different from the other abutting portion 40 in the axial direction of the optical fiber 20. One abutting portion 40 is a separate body from the other abutting portion 40. The abutting portions 40 are connected to each other by, for example, a rod-shaped connecting member 47. One end portion of the connecting member 47 is connected to the center portion of one abutting portion 40, and the other end portion of the connecting member 47 is connected to the center portion of the other abutting portion 40. One abutting portion 40 is disposed adjacent to the other abutting portion 40.

  The pressing force that presses the abutting portion 40 against the fixing jig 30 is indirectly applied to the abutting portion 40 through the connecting member 47.

  In the present embodiment, the connecting member 47 can form the two bent portions 23 at a time. In the present embodiment, the input / output of the optical signal and the blocking of the optical signal can be simultaneously performed with high efficiency.

[Sixth Embodiment / FIG. 7]
Only differences from the above-described embodiments will be described below.
In the fifth embodiment, two abutting portions 40 are provided for the short break switch, but it is not necessary to be limited to this.
As shown in FIG. 7, only one abutting portion 40 is provided. And the abutting part 40 has a substantially oval shape. The abutting portion 40 has a first flat surface portion 43a and a second flat surface portion 43b.

  In the present embodiment, the pressing force can be applied to the abutting portion 40 without waste by the first flat surface portion 43a and the second flat surface portion 43b, and the two bent portions 23 can be formed at once by the abutting portion 40, The two bent portions 23 can be formed with equal force at a time by the flat portion 33 and the abutting portion 40.

[Seventh Embodiment / FIG. 8]
Only differences from the above-described embodiments will be described below.
As shown in FIG. 8, the input / output device 10 described above may be incorporated in an optical communication line switching device 60. The optical communication line switching device 60 includes the input / output device 10, a temporary light blocking mechanism 61, an optical monitoring mechanism 63, an optical switching mechanism 65, and an optical amplification mechanism 67.

  The temporary light blocking mechanism 61 is disposed adjacent to the abutting portion 40. The temporary light blocking mechanism 61 bends the optical fiber 20 so as to lift it, for example, thereby blocking the propagation of the optical signal without cutting the optical fiber 20. That is, quenching is performed.

  The light monitoring mechanism 63 is connected to the input / output optical system 50 and is a system different from the light temporary blocking mechanism 61. The optical switching mechanism 65 is connected to the optical monitoring mechanism 63, and the optical amplification mechanism 67 is connected to the optical switching mechanism 65.

The optical monitor mechanism 63 monitors whether or not an optical signal is propagated to the bypass optical fiber.
The optical switching mechanism 65 works in conjunction with the temporary light blocking mechanism 61 to block and open the propagation of the optical signal in the bypass optical fiber 27 on the input / output optical system side. The optical switching mechanism 65 is opened when the temporary light blocking mechanism 61 is blocked. The optical switching mechanism 65 is blocked when the temporary light blocking mechanism 61 is not blocked.
The optical amplification mechanism 67 amplifies the output light in order to compensate for the loss of the optical signal in the bypass optical fiber 27.

  Before switching from the optical fiber 20 to the bypass optical fiber 27, the input / output device 10 outputs an optical signal to the bypass optical fiber 27 side. Then, the temporary light blocking mechanism 61 is blocked, and at the same time, switching from the optical fiber 20 to the detour optical fiber 27 is performed.

  In the present embodiment, since monitoring is performed by the optical monitoring mechanism 63, switching can be performed after confirming that the optical signal has propagated to the bypass optical fiber. Further, since the input / output device 10 is specialized in quenching, switching can be optimized and the speed can be increased. Since the existing product of the optical switching mechanism is switched in about 3 milliseconds, this embodiment can eliminate the need for additional development. Further, by controlling the time difference between opening and extinguishing in the optical switching mechanism 65, the substantial switching time can be shortened.

Further, the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the components without departing from the scope of the invention in the implementation stage. Further, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment.
For example, some configurations may be deleted from all the components shown in the embodiment. Furthermore, you may combine the component covering different embodiment suitably.
For example, in the third to sixth embodiments, the second member 30b is impermeable to light. However, the present invention is not limited to this, and the second member 30b is transmissive. It may be.
The refractive index of a cover member (not shown) of the optical fiber 20 is substantially the same as the refractive index of a transparent member that is in contact with the cover member. For this reason, the optical signal output pattern or the optical signal input pattern does not depend on the thickness of the cover member. Therefore, the embodiments can be applied to the optical fibers 20 having different cover member thicknesses.

  DESCRIPTION OF SYMBOLS 10 ... Input / output device, 20 ... Optical fiber, 21 ... Midway part, 23 ... Bending part, 25 ... Straight part, 30 ... Fixing jig, 31 ... Curved part, 33 ... Plane part, 40 ... Butting part, 41 ... Curved surface portion, 43... Planar portion, 50... Input / output optical system.

Claims (8)

An optical fiber side input / output device for inputting / outputting optical signals to / from the optical fiber from the side of the optical fiber,
A curved surface portion on which the midway portion is placed to form a bent portion in the midway portion of the straight optical fiber, and the curved surface portion on which the midway portion is placed to form a straight portion in the midway portion A fixing jig having flat portions disposed at both ends of
An abutting portion that strikes the midway portion from the opposite side of the curved surface portion so as to sandwich the midway portion together with the curved surface portion, and forms a bent portion in the midway portion together with the curved surface portion by abutment;
An input / output optical system that inputs and outputs the optical signal so that the optical signal is input to and output from the side to the optical fiber;
Comprising
When the optical signal is input / output to / from the optical fiber from the side, the abutting portion and the curved surface portion form the bent portion so that the optical signal is input / output from the linear portion. An optical fiber side input / output device.   Since the optical signal is input and output from the linear portion, the curvature radius of the bent portion is approximately 2.5 mm or less, and the bending angle of the optical fiber is approximately 165 degrees or more and approximately 170 degrees or less. The optical fiber side input / output device according to claim 1, wherein the butted portion and the curved surface portion form the bent portion.   The optical fiber side input / output device according to claim 2, wherein the abutting portion includes a curved surface portion that sandwiches the midway portion together with the curved surface portion.   The abutting portion further includes a planar portion that is disposed at at least one of both ends of the curved surface portion and sandwiches the midway portion together with the planar portion to form the linear portion. Item 4. The optical fiber side input / output device according to Item 3. Since the two bent portions are disposed, the two fixing jigs are disposed,
Two abutting portions are disposed so as to abut each of the fixing jigs, and the abutting portions are connected by a connecting member, or
The optical fiber side input / output device according to claim 1, wherein one abutting portion is disposed so as to simultaneously abut against the two fixing jigs.   The part of the fixing jig interposed between the input / output optical system and the planar portion that is in contact with the linear portion that inputs and outputs the optical signal includes a transmission member that transmits the optical signal. The optical fiber side input / output device according to any one of claims 1 to 5.   The said abutting part has an application plane part to which the pressing force which presses the said abutting part against the said fixing jig is directly applied, The one of Claim 1 thru | or 6 characterized by the above-mentioned. Optical fiber side input / output device. An optical fiber side input / output method for inputting / outputting an optical signal to / from the optical fiber from the side of the optical fiber,
In order to form a bent part in the middle part of the linear optical fiber on the fixing jig, and to form a straight part in the middle part on which the middle part is placed and the middle part is placed. A flat surface portion disposed at both ends of the curved surface portion,
The abutting part is abutted against the midway part from the opposite side to the curved part so as to sandwich the midway part together with the curved part, and a bent part is formed in the midway part by the abutting part and the curved part by abutment. Forming,
An input / output optical system is disposed in the fixing jig, and the optical signal is input / output from the input / output optical system so that the optical signal is input / output to / from the optical fiber from the side,
When the optical signal is input / output to / from the optical fiber from the side, the abutting portion and the curved surface portion form the bent portion so that the optical signal is input / output from the linear portion. An optical fiber side input / output method characterized by

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