JP2003057488A - Eccentricity quantity measuring instrument for single- fiber ferrule with optical fiber - Google Patents

Abstract

PROBLEM TO BE SOLVED: To measure the eccentricity quantity of the core of a single-fiber ferrule with a fiber while the optical fiber is not twisted. SOLUTION: The eccentricity quantity measuring instrument is provided with a sample table 3 having a V groove and disposed halfway in the optical path between a condenser lens 6 of a light source system and the objective lens of a microscope of a measurement system, a ferrule rotating mechanism which rotates a ferrule 10 on the sample table, a rotatable cassette holder, and a cassette holder rotating mechanism which rotates the cassette holder; and an optical fiber part of the single-fiber ferrule with the fiber which has ferrules at both the ends is stored in a cassette having openings at both the ends and this cassette is loaded in the holder. One ferrule is drawn out of a rotary shaft of the cassette holder rotating mechanism and mounted on the sample table, and the other ferrule is fixed with the other fixture of the rotary shaft; and tow rotating mechanisms are so controlled so that the rotation of the ferrule on the V groove synchronizes with the rotation of the other ferrule fixed to the rotary shaft of the cassette holder rotating mechanism.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an eccentricity measuring device for a single-core ferrule with an optical fiber, which measures the eccentricity of the core of the ferrule for the single-core ferrule with an optical fiber.

[0002]

2. Description of the Related Art An outline of a conventional eccentricity measuring device for a single-core ferrule is composed of a detecting part for mounting and rotating a ferrule and an operating part centering on a computer, and is shown in FIG. Such a device has been put to practical use. The detector is equipped with a light projector below the vibration isolation table, and a V lens is placed in the middle of the optical path between the optical microscope / camera and the condenser lens, which is fixed on the stone surface plate placed above it.
The sample table having the groove is fixed, and the ferrule rotating mechanism including a roller for rotating the ferrule on the V groove is fixed. The anti-vibration device of the anti-vibration table is based on the servo type air spring anti-vibration method. The operation unit is a personal computer disk (DOS / DOS /
V, Pentium III), controller, 17-inch CRT monitor, standard keyboard, mouse, joystick, and printer. The image processing system is installed in the expansion slot of the personal computer and connected to the microscope / camera of the detector. The ferrule rotating mechanism is connected to the personal computer via the controller. To measure, the ferrule placed in the V groove made of zirconia of the detection part is automatically rotated from the operation part, the displacement amount of the fiber hole at each rotation position is captured by image processing, and the ferrule is calculated by the calculation software. Measure the amount of eccentricity with respect to the outer diameter standard. As for the measurement result, the amount of eccentricity is displayed on the monitor screen, printed by the printer, and output as a data file.

An outline of a conventional eccentricity measuring device for a single-core ferrule with an optical fiber is as shown in FIG. 7, in which one ferrule is placed on a fixing jig and fixed by a spring spring. Light is introduced from an external condenser lens, the other ferrule is placed on a sample table, rotated by a roller, and the light emitted therefrom is measured by an optical microscope. Specifically, XYZ fixed on the stone surface plate
A microscope / CCD camera 2 having an objective lens 1 is fixed on an axis adjusting table (not shown). The XYZ-axis adjustment stand is a manual type, and the X-axis stage stroke is ± 1
2.5mm, Y-axis stage stroke ± 3.75m
m, Z axis stage stroke ± 12.5 mm. The optical microscope is a microscope with an infinity correction system objective lens, the measurement field of view is about 220 × 165 μm, and the detection camera is a 1/3 inch CCD camera.
The sample table 3 is fixed in front of the objective lens 1, and next to it,
A ferrule rotating mechanism is provided. The sample table 3 is provided with a V-groove made of zirconia, and the ferrule is mechanically positioned by abutting against a stopper (not shown). The ferrule rotating mechanism has a rotating shaft provided on a fixed support fixed on a stone surface plate, an L-shaped arm rotatably provided on the rotating shaft, and a ferrule rotating on a side surface of one long arm of the L-shaped arm. -Provided with a rotor 4 and a pulley on the other side, a gear for rotating the roller 4 by penetrating the rotary shaft of the pulley, and a motor 5 on the side of the short arm facing upward on the other side. The rotating shaft is connected to a pulley provided on the other side surface, and a belt is hung on the two pulleys to connect them. The ferrule is automatically rotated by this arm retract type roller drive system. The condenser lens 6 is fixed to the stone surface plate. The condenser lens 6 introduces light from a projector under the anti-vibration table by a fiber light guide method, and illuminates from the side opposite to the optical axis of the microscope while sandwiching the ferrule during measurement. The ferrule fixing jig 7 is fixed in front of the condenser lens 6, and the fixing jig 7 is provided with a spring spring 8 for fixing the ferrule. When measuring the eccentricity of a single-core ferrule with an optical fiber, the optical fiber 9 is placed on a stone surface plate, one ferrule 10 is fixed by a spring spring 8 of a ferrule fixing jig 7, and the other ferrule 10 is a sample. Place it in the V groove of the stand 3. The roller 5 is rotated by the rotation of the motor 4, the L-shaped arm is lowered, the ferrule 10 is rotated by the roller 5, the light from the condenser lens 6 is received by the objective lens 1, and the displacement of the fiber hole at each rotation position is performed. The amount of eccentricity with respect to the outer diameter reference of the ferrule is measured by capturing the amount by image processing.

The conventional eccentricity measuring device for a single-core ferrule with an optical fiber described above fixes one ferrule,
The optical fiber is twisted because only the other ferrule is rotated, but it is practically sufficient because the optical fiber is not rotated for measurement. However, if the optical fiber is twisted many times repeatedly for precise measurement, the twist of the optical fiber becomes large, and (1) the stress of the twist is accumulated in the optical fiber, which becomes a load, and the position of the ferrule to be measured is displaced. 2) It is stipulated that the optical fiber should not be bent below a certain radius, but there was a problem that the optical fiber was twisted within its radius of curvature. Further, one ferrule must be placed on a fixing jig and fixed by a spring spring, which is troublesome for work. Further, since the light is introduced from the external condenser lens, the adjustment of the ferrule fixing position becomes complicated.

[0005]

The problem to be solved is that the twisting of the optical fiber which becomes an obstacle in the operation of rotating the ferrule on the V groove of the sample table 3 becomes large.

[0006]

SUMMARY OF THE INVENTION According to the present invention, a single-core ferrule with an optical fiber is housed in a cassette, the cassette is attached to a cassette holder, and the rotation of the ferrule and the rotation of the cassette holder are synchronized with each other, thereby The most important feature is to completely eliminate the twist of the fiber.

[0007]

BEST MODE FOR CARRYING OUT THE INVENTION A single-core ferrule with an optical fiber is housed in a cassette in the optical path between a light introducing system from a condenser lens and a light receiving system consisting of an optical microscope, and the cassette is mounted and fixed in a cassette holder. By rotating the cassette holder with a motor and synchronizing the motor with the motor for rotating the ferrule, it is possible to completely eliminate the twist of the optical fiber.

A first aspect of the invention has a motor for rotating a ferrule on the sample stage provided with a sample stage having a V groove formed in the optical path between the condenser lens of the light source system and the objective lens of the microscope of the measurement system. A ferrule rotating mechanism is provided, and a rotatable cassette holder and a cassette holder rotating mechanism having a motor for rotating the cassette holder are provided.
The rotary shaft of the cassette holder rotating mechanism is provided with a cavity through which a single-core ferrule with an optical fiber passes, and further, ferrule fixtures and fiber fixtures are provided at both ends of the rotary shaft, while openings are provided at both ends. The optical fiber part of the single-core ferrule with optical fibers having ferrules at both ends is stored in the cassette that has it, this cassette is installed in the cassette holder, one ferrule is fixed by the ferrule fixing tool of the rotating shaft, and the other ferrule Is pulled out from the rotation axis of the cassette holder rotation mechanism and placed on the sample table.
Fix the optical fiber part with the fiber fixing device of the rotary shaft,
By controlling the two motors so that the rotation of the ferrule on the groove and the rotation of the other ferrule fixed to the rotation shaft of the cassette holder rotation mechanism are synchronized, the optical fiber is twisted without the optical fiber being twisted. An eccentricity measuring device for a single-core ferrule with an optical fiber, which measures the eccentricity of a single-core ferrule with a fiber.

A second aspect of the invention specifies the ferrule rotating mechanism of the first aspect of the invention, wherein the ferrule rotating mechanism is provided with a rotary shaft on a fixed column and an L-shaped arm rotatably provided on the rotary shaft. , A roller for rotating the ferrule is provided on one side surface of one long arm of the L-shaped arm, and a pulley is provided on the other side surface thereof, and a gear is provided for penetrating the rotation shaft of the pulley to rotate the roller. A motor is provided on a side surface of a short arm facing toward, a rotary shaft of the motor is coupled to a pulley provided on the other side surface, and a belt is hung on the two pulleys to connect them.
By controlling the two motors so that the rotation of the ferrule on the groove and the rotation of the other ferrule fixed to the rotation shaft of the cassette holder rotation mechanism are synchronized, the optical fiber is twisted without the optical fiber being twisted. An eccentricity measuring device for a single-core ferrule with an optical fiber, which measures the eccentricity of a single-core ferrule with a fiber.

A third aspect of the invention further specifies the ferrule rotating mechanism in the second aspect of the invention, wherein the ferrule rotating mechanism is provided with a weight column on the upper end surface in the vicinity of the pulley rotation axis of the long arm. The present invention is characterized in that one or a plurality of magnetized weights with holes can be placed, and two motors are provided so as to synchronize the rotation of the ferrule on the V groove with the rotation of the cassette holder. By measuring the eccentricity amount of the single-fiber ferrule with an optical fiber in a state where the optical fiber is not twisted.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the drawings. FIG. 1 is a perspective view showing an outline of an eccentricity measuring device for a single-core ferrule with an optical fiber according to an embodiment of the present invention.
6 and 9, 10 are the same as in FIG. 7. Also, 1
6 is a motor for rotating the cassette holder, 18 is a cassette, 19 is a weight support, and 20 is a magnet-containing weight. In the illustrated example, one weight containing a magnet is placed.

The main part of the present invention is shown in FIG. The columns 11 and 11 are fixed on a stone surface plate, and the column 11 is provided with a rotary shaft. The rotary shaft is provided with a cavity through which a single-core ferrule with an optical fiber passes, and both ends of the rotary shaft are provided. A ferrule fixing tool 12 and a fiber fixing tool 13 are provided, the cassette holder 14 is fixed to the rotation axis between the columns 11, 11, and a cassette fixing leaf spring 15 is provided on the upper part of the cassette holder 14 so as to be opened and closed. A pulley is provided on the rotary shaft of the lens 6 side, and a belt 17 is connected between the pulley and a pulley provided on a motor 16 fixed to the stone surface plate so that the cassette holder can be rotated. On the other hand, an optical fiber portion of a single-core ferrule with optical fibers having ferrules at both ends is stored in a cassette 18 having openings at both ends, and this cassette is mounted in a cassette holder, and one ferrule is fixed to a ferrule of a rotating shaft. The other ferrule is pulled out from the rotating shaft of the cassette holder rotating mechanism and placed in the V groove on the sample table, and the optical fiber portion is fixed by the fiber fixing device 13 of the rotating shaft.

Next, an outline of a method for measuring the eccentricity of a ferrule using the eccentricity measuring device for a single-core ferrule with an optical fiber according to the present invention will be described. First, there are single-core ferrules to be measured that have outer diameters of 1.25 mm and 2.5 mm, depending on the type of optical connector. The measurement item is the eccentric amount of the fiber hole of the ferrule, the inner diameter of the ferrule hole is 125 μm, and the degree of eccentricity with respect to the outer diameter reference is measured (the inner diameter value itself is not measured). The ferrule 10 is, as shown in FIG.
It is composed of a ferrule body 10 and a SUS steel flange 10a, and the optical cable extends from the flange 10a side.

The outline of the procedure for measuring the amount of eccentricity of a single-core ferrule with an optical fiber is as follows: (1) A ferrule set ferrule is placed in a V-groove on a sample table and abutted against a stopper (not shown), Position mechanically. It is shown in 1a of FIG. 4 (no need for precise positioning). (2) Set the rotary drive arm. When the outer diameter of the ferrule is 1.25 mm, set one magnet-containing weight, and when it is 2.5 mm, set two weights. The number of magnet-containing weights can be adjusted as desired. (3) Condition setting (If it is adjusted once, it is not necessary to set each time.) (A) Focus adjustment The entire inner diameter (125 μm) of the ferrule is captured by the camera and displayed on the monitor. Focus while watching the measurement surface on the monitor. This is shown in 1b of FIG. (B) Parameter setting Parameters such as the number of measurement points are set as necessary. The number of measurement points is usually 4 (every 90 °). If necessary, it can be set to 8 points. (4) Measurement command An example of four points (every 90 °) in the normal case will be described. When the measurement start icon button is pressed, first the preliminary rotation for determining the position of the ferrule is performed, and then the center of the inner diameter projected on that is measured. The center coordinates of the projected inner diameter are calculated from the edge of the projected inner diameter by a regression circle calculation. It is shown in FIG. Instead of the regression circle calculation, an inscribed circle or circumscribed circle calculation mode can be selected. The center coordinate is measured at an arbitrary rotational position, and this coordinate is set as the 0 ° position. Then, the center of the inner diameter is similarly obtained by rotating 90 °, and further the center coordinates at 180 ° and 270 ° are obtained. The locus of the center coordinates is drawn as shown in FIG. When the measurement of the centers at the four points is completed, the amount of eccentricity is calculated. A regression circle is calculated from the four center lines to find the center and radius. The amount of eccentricity is the length of the radius. The result is displayed on the CRT monitor screen. The measurement results are printed by a printer or output to a file.

[0015]

As described above, the eccentricity measuring device for a single-core ferrule with an optical fiber according to the present invention has the following features (1): The optical fiber is completely free from twisting. (2) By preparing a plurality of cassettes, the preparation for measurement preparation is easy,
(3) The inconvenience of measurement due to the difference in the length of the optical fiber is caused by storing the optical cable in the cassette.
It disappeared completely because the difference in length was resolved. Also,
According to the constituent features described in claim 2, (4) it becomes easy to set the single-core ferrule with an optical fiber in the V groove of the detection unit, and (5) control from the operation unit becomes easy. Further, according to the constituent features described in claim 3, (6) it has become possible to accurately adjust the rotation of the single-core ferrule with an optical fiber. (7) Some twist stress is accumulated in the optical fiber. However, since such a load can be suppressed by the weight, the position of the ferrule to be measured does not shift. (7) The weight does not vibrate because the weight has a magnet, so the ferrule measurement is affected. It has no effect.

[Brief description of drawings]

FIG. 1 is a perspective view schematically showing an eccentricity measuring device for a single-core ferrule with an optical fiber according to the present invention.

FIG. 2 is a schematic view showing a main part of the present invention (Example).

FIG. 3 is an explanatory diagram showing XYZ axis definitions when measuring a ferrule.

FIG. 4 is an explanatory diagram showing a procedure 1 of measuring the amount of eccentricity. 1a) The ferrule is placed on the V groove and rotated by a roller. 1b) The entire inner diameter of the ferrule is captured by a camera and displayed on a monitor.

FIG. 5 is an explanatory diagram showing a procedure 2 of measuring the amount of eccentricity. The center coordinates of the projected inner diameter are calculated by image processing.

FIG. 6 is an explanatory diagram showing a procedure 3 of measuring the amount of eccentricity. The amount of eccentricity is calculated from the locus of the center point.

FIG. 7 is a schematic perspective view of a conventional example in which one ferrule is fixed by a spring.

FIG. 8 is a schematic front view showing the entire conventional single-core ferrule eccentricity measuring device.

[Explanation of symbols]

1 Objective lens 2 Microscope / CCD camera Sample stand with 3 V groove 4 roller 5 Motor that rotates the roller 4 6 Condensing lens 7 Ferrule fixing jig 8 Spring spring to fix the ferrule 9 optical fiber 10 ferrules 11 Support of cassette holder rotation mechanism 12 ferrule fixture 13 Fiber fixture 14 cassette holder 15 Openable and closable cassette fixing leaf spring 16 Motor for rotating cassette holder 17 Belt 18 Optical fiber storage cassette 19 Weight support 20 Weight with magnet

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[Procedure amendment]

[Submission date] April 19, 2002 (2002.4.1)
9)

[Procedure Amendment 1]

[Document name to be amended] Statement

[Name of item to be amended] Claims

[Correction method] Change

[Correction content]

[Claims]

[Procedure Amendment 2]

[Document name to be amended] Statement

[Name of item to be corrected] 0003

[Correction method] Change

[Correction content]

An outline of a conventional eccentricity measuring device for a single-core ferrule with an optical fiber is as shown in FIG. 7, in which one ferrule is placed on a fixing jig and fixed by a spring spring. Light is introduced from an external condenser lens, the other ferrule is placed on a sample table, rotated by a roller, and the light emitted therefrom is measured by an optical microscope. Specifically, XYZ fixed on the stone surface plate
A microscope / CCD camera 2 having an objective lens 1 is fixed on an axis adjusting table (not shown). The XYZ-axis adjustment stand is a manual type, and the X-axis stage stroke is ± 1
2.5mm, Y-axis stage stroke ± 3.75m
m, Z axis stage stroke ± 12.5 mm. The optical microscope is a microscope with an infinity correction system objective lens, the measurement field of view is about 220 × 165 μm, and the detection camera is a 1/3 inch CCD camera.
The sample table 3 is fixed in front of the objective lens 1, and next to it,
A ferrule rotating mechanism is provided. The sample table 3 is provided with a V-groove made of zirconia, and the ferrule is mechanically positioned by abutting against a stopper (not shown). The ferrule rotating mechanism has a rotating shaft provided on a fixed support fixed on a stone surface plate, an L-shaped arm rotatably provided on the rotating shaft, and a ferrule rotating on a side surface of one long arm of the L-shaped arm. -Provided with a rotor 4 and a pulley on the other side, a gear for rotating the roller 4 by penetrating the rotary shaft of the pulley, and a motor 5 on the side of the short arm facing upward on the other side. The rotating shaft is connected to a pulley provided on the other side surface, and a belt is hung on the two pulleys to connect them. The ferrule is automatically rotated by this arm retract type roller drive system. The condenser lens 6 is fixed to the stone surface plate. The condenser lens 6 introduces light from a projector under the anti-vibration table by a fiber light guide method, and illuminates from the side opposite to the optical axis of the microscope while sandwiching the ferrule during measurement. The ferrule fixing jig 7 is fixed in front of the condenser lens 6, and the fixing jig 7 is provided with a spring spring 8 for fixing the ferrule. When measuring the eccentricity of a single-core ferrule with an optical fiber, the optical fiber 9 is placed on a stone surface plate, one ferrule 10 is fixed by a spring spring 8 of a ferrule fixing jig 7, and the other ferrule 10 is a sample. Place it in the V groove of the stand 3. The roller 5 is rotated by the rotation of the motor 4, the L-shaped arm is lowered, the ferrule 10 is rotated by the roller 5, the light from the condenser lens 6 is received by the objective lens 1, and the optical fiber hole at each rotation position is rotated. The amount of displacement is captured by image processing, and the amount of eccentricity with respect to the outer diameter reference of the ferrule is measured.

[Procedure 3]

[Document name to be amended] Statement

[Correction target item name] 0006

[Correction method] Change

[Correction content]

[0006]

According to the present invention, a single-core ferrule with an optical fiber is housed in a cassette, the cassette is mounted in a cassette holder, and the rotation of the ferrule and the rotation of the cassette holder are synchronized with each other, thereby The most important feature is to completely eliminate the twist of the fiber.

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0007

[Correction method] Change

[Correction content]

[0007]

BEST MODE FOR CARRYING OUT THE INVENTION A single-core ferrule with an optical fiber is placed in a cassette in the middle of an optical path between a light introducing system from a condenser lens and a light receiving system including an optical microscope, and the cassette is mounted and fixed in a cassette holder. By rotating the cassette holder with a motor and synchronizing the motor with the motor for rotating the ferrule, it is possible to completely eliminate the twist of the optical fiber.

[Procedure Amendment 5]

[Document name to be amended] Statement

[Correction target item name] 0008

[Correction method] Change

[Correction content]

A first aspect of the invention has a motor for rotating a ferrule on the sample stage provided with a sample stage having a V groove formed in the optical path between the condenser lens of the light source system and the objective lens of the microscope of the measurement system. A ferrule rotating mechanism is provided, and a rotatable cassette holder and a cassette holder rotating mechanism having a motor for rotating the cassette holder are provided.
The rotary shaft of the cassette holder rotating mechanism is provided with a cavity through which a single-core ferrule with an optical fiber passes, and further, ferrule fixtures and fiber fixtures are provided at both ends of the rotary shaft, while openings are provided at both ends. The optical fiber part of the single-core ferrule with optical fibers having ferrules at both ends is stored in the cassette that has it, this cassette is mounted in the cassette holder, one ferrule is fixed by the ferrule fixing tool of the rotating shaft, and the other ferrule is fixed. Is pulled out from the rotary shaft of the cassette holder rotating mechanism and placed on the sample table, the optical fiber part is fixed by a fiber fixing tool of the rotary shaft, the ferrule on the V groove is rotated and the other is fixed to the rotary shaft of the cassette holder rotating mechanism. By controlling the two motors so as to synchronize with the rotation of the ferrule, It is eccentricity measuring apparatus for an optical fiber with a single fiber ferrule, characterized in that to measure the eccentricity with the optical fiber single fiber ferrule.

[Procedure correction 6]

[Document name to be amended] Statement

[Correction target item name] 0010

[Correction method] Change

[Correction content]

A third aspect of the invention further specifies the ferrule rotating mechanism in the second aspect of the invention, wherein the ferrule rotating mechanism is provided with a weight column on the upper end surface in the vicinity of the pulley rotation axis of the long arm. The present invention is characterized in that one or a plurality of weighted magnet-containing weights can be placed, and two motors are provided so as to synchronize the rotation of the ferrule on the V groove with the rotation of the cassette holder. By measuring the eccentricity amount of the single-fiber ferrule with an optical fiber in a state where the optical fiber is not twisted.

[Procedure Amendment 7]

[Document name to be amended] Statement

[Correction target item name] 0011

[Correction method] Change

[Correction content]

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the drawings. FIG. 1 is a perspective view showing an outline of an eccentricity measuring device for a single-core ferrule with an optical fiber according to an embodiment of the present invention.
6 and 9, 10 are the same as in FIG. 7. Also, 1
6 is a motor for rotating the cassette holder, 18 is a cassette, 19 is a weight column, and 20 is a magnet-containing weight. In the illustrated example, one weight containing a magnet is placed.

[Procedure Amendment 8]

[Document name to be amended] Statement

[Correction target item name] 0012

[Correction method] Change

[Correction content]

The main part of the present invention is shown in FIG. The columns 11 and 11 are fixed on a stone surface plate, and the column 11 is provided with a rotary shaft. The rotary shaft is provided with a cavity through which a single-core ferrule with an optical fiber passes, and both ends of the rotary shaft are provided. The ferrule fixing tool 12 and the fiber fixing tool 13 are provided, the cassette holder 14 is fixed to the rotating shaft between the columns 11, 11, and the cassette fixing leaf spring 15 is provided on the upper part of the cassette holder 14 so as to be opened and closed. A pulley is provided on the rotary shaft of the lens 6 side, and a belt 17 is connected between the pulley and a pulley provided on a motor 16 fixed to the stone surface plate so that the cassette holder can be rotated. On the other hand, an optical fiber portion of a single-core ferrule with optical fibers having ferrules at both ends is stored in a cassette 18 having openings at both ends, and this cassette is mounted on a cassette holder, and one ferrule is fixed to a ferrule on a rotating shaft. The other ferrule is pulled out from the rotating shaft of the cassette holder rotating mechanism and placed in the V groove on the sample table, and the optical fiber portion is fixed by the fiber fixing device 13 of the rotating shaft.

[Procedure Amendment 9]

[Document name to be amended] Statement

[Correction target item name] 0013

[Correction method] Change

[Correction content]

Next, an outline of a method for measuring the eccentricity of a ferrule using the eccentricity measuring device for a single-core ferrule with an optical fiber according to the present invention will be described. First, there are single-core ferrules to be measured that have outer diameters of 1.25 mm and 2.5 mm, depending on the type of optical connector. The measurement item is the eccentric amount of the optical fiber hole of the ferrule, the inner diameter of the ferrule hole is 125 μm, and the degree of eccentricity with respect to the outer diameter reference is measured (the inner diameter value itself is not measured). The ferrule 10 is, as shown in FIG.
It is composed of a ferrule body 10 and a SUS steel flange 10a, and the optical cable extends from the flange 10a side. The XYZ axis definition at the time of ferrule measurement is the third
As shown in the figure.

[Procedure Amendment 10]

[Document name to be amended] Statement

[Name of item to be corrected] 0015

[Correction method] Change

[Correction content]

[0015]

As described above, according to the eccentricity measuring device for a single-core ferrule with an optical fiber according to the present invention, (1) the twisting of the optical fiber is completely eliminated by the constituent features described in claim 1. (2) By preparing multiple cassettes, the setup for measurement preparation is easy, and
Beauty (3) inconvenience of the measuring due to the difference in length of the optical fiber, by storing the optical cable into the cassette,
For the difference in length is eliminated, it disappeared completely. Further, according to the constituent features described in claim 2, (4) it becomes easy to set the single-core ferrule with an optical fiber in the V groove of the detection section, and (5) the control from the operation section becomes easy. became. Further, according to the constituent features of claim 3, (6) the twisting stress is somewhat accumulated in the optical fiber.
Even so, the load of that degree can be suppressed by the weight.
The position of the ferrule to be measured can be misaligned in order to be able to
There is no, and (7) because it is a weight with a magnet
Because the weight does not vibrate even when the roller rotates,
The light does not affect the ferrule measurement.
You can precisely adjust the rotation of the single-core ferrule with fiber.
And became possible.

Claims (3)

[Claims] 1. A ferrule rotating mechanism having a motor for rotating a ferrule on the sample stage, wherein a sample stage having a V groove is provided in the optical path between the condenser lens of the light source system and the objective lens of the microscope of the measurement system. A cassette holder rotating mechanism having a rotatable cassette holder and a motor for rotating the cassette holder is provided, and a cavity through which a single-core ferrule with an optical fiber passes is provided in the rotation shaft of the cassette holder rotating mechanism. A ferrule fixing tool and a fiber fixing tool are provided at both ends of the rotation shaft, and on the other hand, an optical fiber portion of a single-core ferrule with optical fibers having ferrules at both ends is stored in a cassette having openings at both ends. To the cassette holder, fix one ferrule with the ferrule fixture on the rotating shaft, and The module is pulled out from the rotary shaft of the cassette holder rotating mechanism and placed on the sample table, the optical fiber part is fixed by the fiber fixing tool of the rotary shaft, and it is fixed to the rotation of the ferrule on the V groove and the rotary shaft of the cassette holder rotating mechanism. By controlling the two motors so as to synchronize the rotation of the ferrule, the eccentricity of the single-core ferrule with an optical fiber is measured in a state where the optical fiber is not twisted. Eccentricity measuring device for single-core ferrules. 2. A sample stage having a V groove formed therein and a ferrule rotating mechanism having a motor for rotating a ferrule on the sample stage are provided in the optical path between the condenser lens of the light source system and the objective lens of the microscope of the measurement system. The ferrule rotating mechanism is provided with a rotating shaft on a fixed support, an L-shaped arm rotatably provided on the rotating shaft, a roller for rotating the ferrule on one side surface of one long arm of the L-shaped arm, and the other. A pulley is provided on the side surface of the, a gear for rotating the roller is provided by penetrating the rotation axis of the pulley, a motor is provided on the side surface of the short arm facing the other side, and the rotation axis of the motor is provided on the other side surface. It is connected to a pulley, a belt is hung on the two pulleys to connect them, and a rotatable cassette holder and a cassette holder rotating mechanism having a motor for rotating the cassette holder are provided. The cassette holder rotation mechanism has a rotation shaft provided with a cavity through which a single-core ferrule with an optical fiber passes, and further, a ferrule fixing tool and a fiber fixing tool are provided at both ends of the rotation axis, while both ends are provided. An optical fiber part of a single-core ferrule with optical fibers having ferrules at both ends is stored in a cassette having an opening, this cassette is mounted in a cassette holder, and one ferrule is fixed by a ferrule fixing tool of a rotating shaft, and the other is fixed. The ferrule is pulled out from the rotating shaft of the cassette holder rotating mechanism and placed on the sample table, the optical fiber part is fixed by the fiber fixing tool of the rotating shaft, and the ferrule on the V groove and the rotating shaft of the cassette holder rotating mechanism are fixed. By controlling the two motors so as to synchronize the rotation of the ferrule, the optical fiber is not twisted. Eccentricity measuring apparatus of single core ferrule with an optical fiber and measuring the eccentricity with the optical fiber single fiber ferrule. 3. A sample stage having a V groove formed therein and a ferrule rotating mechanism having a motor for rotating a ferrule on the sample stage are provided in the optical path between the condenser lens of the light source system and the objective lens of the microscope of the measurement system. The ferrule rotating mechanism is provided with a rotating shaft on a fixed support, an L-shaped arm rotatably provided on the rotating shaft, a roller for rotating the ferrule on one side surface of one long arm of the L-shaped arm, and the other. A pulley is provided on the side surface of the, a gear for rotating the roller is provided by penetrating the rotation axis of the pulley, a motor is provided on the side surface of the short arm facing the other side, and the rotation axis of the motor is provided on the other side surface. It is connected to a pulley, a belt is hung on the two pulleys to connect them, and a long arm is provided with a weight support on the upper end surface near the pulley rotation axis. In addition, a rotatable cassette holder and a cassette holder rotating mechanism having a motor for rotating the cassette holder are provided, and the rotation shaft of the cassette holder rotating mechanism has a cavity through which a single-core ferrule with a fiber passes. Is provided, and further, a ferrule fixing tool and a fiber fixing tool are provided at both ends of the rotating shaft,
On the other hand, the optical fiber part of a single-core ferrule with optical fibers having ferrules at both ends is stored in a cassette having openings at both ends, and this cassette is mounted in a cassette holder, and one ferrule is a ferrule fixing tool for a rotating shaft. The other ferrule is pulled out from the rotating shaft of the cassette holder rotating mechanism and placed on the sample table, and the optical fiber part is fixed by the fiber fixing tool of the rotating shaft. The ferrule on the V groove and the cassette holder rotating mechanism are fixed. By controlling the two motors so as to synchronize with the rotation of the ferrule fixed on the rotation axis, it is possible to measure the eccentricity of the single-core ferrule with an optical fiber without the optical fiber being twisted. An eccentricity measuring device for a single-core ferrule with an optical fiber. (Weight with magnet, refer to claim 2)