JP2014013310A - Fusion splicing apparatus, and fusin splicing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fusion splicing apparatus and a fusion splicing method that facilitate a fusion splice between a plurality of built-in fibers arrayed in two rows and a plurality of optical fibers of a multicore optical cable.SOLUTION: A fusion splicing apparatus 1A comprises a connector-side support part 14 that includes a V-groove 14a that stores a fist built-in fiber 23a and a V-groove 14b that stores a second built-in fiber 23b. The V-grooves 14a and 14b have the first built-in fiber 23 arranged in one area A1 partitioned by a reference flat plane P1 and the second built-in fiber 23b arranged in other area A2, and are formed such that the first built-in fiber 23a and the second built-in fiber 23b are alternately arrayed when viewed from a line perpendicular to the reference flat plane P1.

Description

  The present invention relates to a fusion splicer and a fusion splicing method.

  Patent Document 1 describes a one-dimensional multi-fiber optical connector in which a plurality of optical fibers are arranged in a horizontal row. Patent Document 1 describes a two-dimensional multi-fiber optical connector in which optical fibers are arranged in both vertical and horizontal directions.

  Patent Document 2 discloses a fusion splicer that fuses a short optical fiber in an optical connector and the optical fiber of the optical fiber cable when the optical connector is attached to the optical fiber cable in the field such as on-site optical wiring. And a method of assembling the optical connector.

  Non-Patent Document 1 describes a technique related to an on-site optical connector using a fusion technique.

JP 2004-170482 A International Publication No. 2008/059443

Tetsuya Noda and five others, “Development of on-site connector with built-in fusion”, IEICE technical report. OFT, Optical Fiber Application Technology, 107 (451), pp. 55-58, January 17, 2008

  In recent years, for example, for the simplification of construction of FTTx, which is rapidly progressing, and the ease of maintenance, there is an increasing demand for an optical connector that can be attached locally. For example, as described in Patent Document 2 and Non-Patent Document 1, a field-installable optical connector includes a short optical fiber. When the optical connector is assembled to an optical fiber cable, this short internal The fiber and the optical fiber of the optical fiber cable need to be fusion-bonded to each other.

  With the recent increase in communication data volume, multi-core optical fiber cables in which a plurality of optical fibers are assembled are being put into practical use. Then, the optical connector can be installed locally by fusion-bonding a plurality of built-in fibers of the optical connector assembled to the multi-core optical fiber cable and a plurality of optical fibers of the multi-fiber optical fiber cable. It is desirable.

  As an optical connector for a multi-fiber optical fiber cable, there is one in which optical fibers are arranged in two rows at a connection end face with a receptacle, such as a 24-fiber MPO connector. In order to make such an optical connector field-installable, it is necessary to fusion-connect a plurality of rows of built-in fibers built in the optical connector and a plurality of optical fibers of a multi-core optical fiber cable. However, in the conventional fusion splicing device, for example, a plurality of optical fibers are accommodated in a plurality of V grooves arranged in a direction orthogonal to the axial direction of the optical fiber, and positioning is performed while arc fusion or the like is performed. Do wearing. Such a method is useful when the built-in fibers are arranged in a row, but when the built-in fibers are arranged in two rows, such as a 24-fiber MPO connector, the optical fiber of the multi-core optical fiber cable is used. In some cases, it becomes difficult to make a fusion splice.

  The present invention has been made in view of such a problem, and a fusion splicing that facilitates a fusion splicing between a plurality of built-in fibers arranged in two rows and a plurality of optical fibers of a multi-core optical fiber cable. It is an object to provide a machine and a fusion splicing method.

  In order to solve the above-described problems, a fusion splicer according to the present invention includes a plurality of optical fiber end portions of a multi-core optical fiber cable and a ferrule of a multi-fiber optical connector with a direction along a predetermined axis as a longitudinal direction. A fusion splicer for fusion-splicing the ends of a plurality of built-in fibers held together to each other, wherein two or more built-in fibers (hereinafter referred to as first built-in fibers) among the plurality of built-in fibers Connector having two or more first grooves for accommodating two or more second grooves for accommodating other two or more built-in fibers (hereinafter referred to as second built-in fibers) among a plurality of built-in fibers. Side support, two or more third grooves that accommodate optical fibers fused to the first built-in fiber (hereinafter referred to as first optical fiber), and light fused to the second built-in fiber Fiber (hereinafter referred to as second optical fiber) A cable-side support portion having two or more fourth grooves to be accommodated, and a discharge portion having a pair of electrodes for discharging in a space between the connector-side support portion and the cable-side support portion, The first built-in fiber is disposed in one of the two regions partitioned by the reference plane including the axis, and the second built-in fiber is disposed in the other region. The first built-in fiber is viewed from the perpendicular direction of the reference plane. First and second grooves are formed so that the built-in fiber and the second built-in fiber are alternately arranged, the first optical fiber is disposed in one region, and the second optical fiber is disposed in the other region. And the third and fourth grooves are formed so that the first optical fiber and the second optical fiber are alternately arranged as viewed from the direction perpendicular to the reference plane.

  Further, the fusion splicing method according to the present invention includes a plurality of optical fiber end portions of a multi-fiber optical fiber cable and a plurality of optical fibers held by the ferrule of the multi-fiber optical connector with a direction along a predetermined axis as a longitudinal direction. Two or more first grooves for accommodating two or more built-in fibers (hereinafter referred to as first built-in fibers) among a plurality of built-in fibers. , And the first and second connector-side support portions having two or more second grooves for accommodating two or more other built-in fibers (hereinafter referred to as second built-in fibers) among the plurality of built-in fibers. The first and second built-in fibers are respectively accommodated in the grooves, and two or more third grooves that contain optical fibers (hereinafter referred to as first optical fibers) to be fused to the first built-in fibers, and Optical fiber fused to the two built-in fibers Receiving the first and second optical fibers in the third and fourth grooves of the cable-side support portion having two or more fourth grooves for receiving the Iva (hereinafter referred to as second optical fiber); A step of fusion-bonding the ends of the plurality of optical fibers and the ends of the plurality of built-in fibers to each other by performing discharge in the space between the connector side support portion and the cable side support portion, In the first and second grooves, the first built-in fiber is arranged in one of the two regions divided by the reference plane including the predetermined axis, and the second built-in fiber is arranged in the other region. The first built-in fiber and the second built-in fiber are formed so as to be alternately arranged when viewed from the direction perpendicular to the plane, and the first and second optical fibers are arranged in one region of the third and fourth grooves. The second optical fiber in the other region Is arranged, the first optical fiber when viewed from the normal direction of the reference plane and the second optical fiber is characterized in that it is formed so as to align alternately.

  In the fusion splicer and the fusion splicing method described above, the first and second grooves of the connector side support portion support a plurality of built-in fibers as follows. In other words, the connector-side support portion connects two or more first built-in fibers of the plurality of built-in fibers and the other two or more second built-in fibers to both sides of the reference plane (one region and Place in the other area. Then, these are arranged so that the first built-in fibers and the second built-in fibers are alternately arranged as viewed from the direction perpendicular to the reference plane. Furthermore, the 3rd and 4th groove | channels of a cable side support part arrange | position the several optical fiber of a multi-core optical fiber cable similarly to a built-in fiber. Thus, even when the optical fibers of the built-in fiber and the multi-core optical fiber cable are arranged in two rows, such as a 24-fiber MPO connector, a plurality of grooves (first to fourth grooves ( The built-in fiber and the optical fiber of the multi-core optical fiber cable can be positioned by the (typically V-groove).

  Thus, according to the above-described fusion splicer and fusion splicing method, a plurality of built-in fibers and optical fibers of a multi-core optical fiber cable arranged in two rows can be accommodated in a plurality of grooves. Can be easily positioned. Therefore, it is possible to facilitate the fusion splicing between these built-in fibers and the plurality of optical fibers of the multi-core optical fiber cable.

  In the fusion splicer and the fusion splicing method, the end of at least one of the first built-in fiber and the second built-in fiber is along the reference plane in a cross section perpendicular to the predetermined axis. First and second grooves are formed so as to be arranged side by side on a straight line, and the end of the optical fiber fused to at least one of the built-in fibers is straight on a cross section perpendicular to a predetermined axis. The third and fourth grooves may be formed so as to be arranged side by side. Alternatively, in the fusion splicer and the fusion splicing method described above, the end of at least one of the first built-in fiber and the second built-in fiber moves away from the reference plane in a cross section perpendicular to the predetermined axis. First and second grooves are formed so as to be arranged side by side on a curved line that swells in the direction, and a cross section in which an end of an optical fiber fused to at least one of the built-in fibers is perpendicular to a predetermined axis The third and fourth grooves may be formed so as to be arranged side by side on the curved line. In any of these forms, according to the fusion splicer and the fusion splicing method described above, fusion between a plurality of built-in fibers arranged in two rows and a plurality of optical fibers of a multi-core optical fiber cable is possible. The incoming connection can be facilitated. In particular, according to the configuration in which the built-in fiber and the optical fiber are arranged side by side on a curved line that swells away from the reference plane, the fusion site can be arranged along the constant temperature region in the discharge path formed by the discharge part. The variation in the degree of fusion can be suppressed.

  In the fusion splicer, the line connecting the pair of electrodes when viewed from the direction of the predetermined axis is between the first built-in fiber and the first optical fiber and the second built-in fiber and the second optical fiber. A pair of electrodes may be arranged so as to be positioned at each other. Thereby, the dispersion | variation in the grade of the melt | fusion by discharge can be suppressed.

  According to the fusion splicer and the fusion splicing method according to the present invention, it is possible to facilitate fusion splicing between a plurality of built-in fibers arranged in two rows and a plurality of optical fibers of a multi-core optical fiber cable.

FIG. 1 is a perspective view showing an appearance of a fusion splicer used in a fusion splicing method according to an embodiment. FIG. 2 is an enlarged view of a fusion processing unit provided in the fusion splicer shown in FIG. FIG. 3 is a perspective view showing the external appearance of the holder, and shows a state in which the lid member of the holder is closed. FIG. 4 is a perspective view showing the outer appearance of the holder, and shows a state in which the lid member of the holder is opened. FIG. 5 is an enlarged perspective view showing the appearance of the cable side support part and the connector side support part. FIG. 6 is a cross-sectional view taken along the line III-III of the connector side support portion shown in FIG. 5 and shows a cross section perpendicular to a predetermined axis. FIG. 7 is a cross-sectional view taken along the line IV-IV of the cable side support shown in FIG. 5 and shows a cross section perpendicular to a predetermined axis. FIG. 8 is a diagram schematically showing the state of arc discharge, and shows a state seen from the X-axis direction. FIG. 9 is a diagram illustrating an example of a temperature distribution in arc discharge. FIG. 10 is a view showing a cross section of the connector-side support portion as a modified example. FIG. 11 is a diagram showing a cross section of the cable side support portion as a modification.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments of a fusion splicer and a fusion splicing method according to the present invention will be described in detail with reference to the accompanying drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted.

  FIG. 1 is a perspective view showing an appearance of a fusion splicer 1A used in a fusion splicing method according to an embodiment of the present invention. FIG. 2 is an enlarged view of the fusion processing unit 10 provided in the fusion splicer 1A shown in FIG. The fusion splicer 1A of the present embodiment is held at the end of a plurality of optical fibers F5 constituting the multi-core optical fiber cable F1 and the ferrule of the multi-fiber optical connector at the site of construction of the optical communication network. This is an apparatus for fusion-splicing the ends of a plurality of short built-in fibers 23 to each other. The multi-fiber optical connector of this embodiment is, for example, an MPO (Multi-fiber Push-on) type optical connector. The multi-fiber optical connector is connected to the MPO receptacle via an optical adapter.

  The fusion splicer 1 </ b> A includes a fusion processing unit 10. The fusion processing unit 10 is usually provided on the upper surface of the apparatus covered by the opening / closing cover 16. As shown in FIG. 2, the fusion processing unit 10 includes a cable mounting unit 12, a cable side support unit 13, a connector side support unit 14, and a discharge unit 15. In addition, the fusion processing unit 10 further includes a holder 30 and a holder mounting unit 11.

  The cable mounting portion 12 is a portion that holds the multi-core optical fiber cable F1 along the predetermined axis X. The cable-side support portion 13 is a portion that positions while supporting the end portions of the plurality of optical fibers F5 exposed from the tip of the multi-core optical fiber cable F1, and a plurality of cables for accommodating the plurality of optical fibers F5. V-groove. The cable side support portion 13 is arranged side by side in the direction of the predetermined axis X with respect to the cable mounting portion 12.

  The holder 30 accommodates and protects the ferrule during transportation of the multi-fiber optical connector, and is mounted on the holder mounting portion 11 on the predetermined axis X and held by the ferrule when using the fusion splicer 1A. A plurality of built-in fibers 23 are fixed. The plurality of built-in fibers 23 are held by the ferrule with the direction along the predetermined axis X as the longitudinal direction, and extend from the side surface of the holder 30 in the direction X. By mounting such a holder 30 on the holder mounting portion 11, the plurality of built-in fibers 23 are attached to the fusion processing unit 10 together with the holder 30, and the plurality of built-in fibers 23 are generally attached to the fusion position. Is positioned.

  Here, FIG.3 and FIG.4 is a perspective view which shows the external appearance of the holder 30 of this embodiment. FIG. 3 shows a state in which the lid member 32 of the holder 30 is closed, and FIG. 4 shows a state in which the lid member 32 is opened. This holder 30 accommodates the connector plug 20 containing a ferrule. More specifically, the holder 30 accommodates the connector plug 20 in which the stopper 22 is attached to the plug frame 21 surrounding the ferrule in a state in which the dust cap 24 (see FIG. 4) is attached to the ferrule. The plurality of built-in fibers 23 and connector plugs 20 attached in advance are protected.

  The holder 30 includes a holder main body 31 and a lid member 32. The holder main body 31 has a plug housing portion 31 a (see FIG. 4) that is a recess for housing the plug frame 21. The lid member 32 is attached to the holder body 31 so as to be openable and closable around the rotation support shaft 32a as a fulcrum, and covers the plug housing portion 31a and presses the plug frame 21.

  As shown in FIG. 4, a plurality of V grooves for positioning and supporting the plurality of built-in fibers 23 are formed on the upper end surface of the front end wall 31 b of the holder body 31 through which the built-in fibers 23 pass. . When the lid member 32 is in the closed state, the plurality of built-in fibers 23 positioned in the plurality of V grooves are pressed against the front end wall 31b.

  Refer to FIG. 2 again. The connector-side support portion 14 is a portion that is positioned while supporting the end portions of the plurality of built-in fibers 23 extending from the holder 30, and has a plurality of V-grooves for accommodating the plurality of built-in fibers 23. The connector side support portion 14 is arranged side by side in the direction of the predetermined axis X with respect to the holder 30 and is arranged between the holder 30 and the cable side support portion 13.

  The discharge unit 15 includes a pair of electrodes 15 a and 15 b disposed between the cable side support unit 13 and the connector side support unit 14. The pair of electrodes 15a and 15b performs arc discharge in a space between the cable side support portion 13 and the connector side support portion 14, and a plurality of built-in fibers 23 and a plurality of optical fibers F5 that are abutted in the space. Are fused to each other.

  Here, the detailed structure of the cable side support part 13 and the connector side support part 14 of this embodiment is demonstrated.

  FIG. 5 is an enlarged perspective view showing the external appearance of the cable side support portion 13 and the connector side support portion 14. In addition, the space | gap 53 provided between the cable side support part 13 and the connector side support part 14 is a space where arc discharge is performed by a pair of electrodes 15a and 15b (refer FIG. 2). FIG. 6 is a cross-sectional view taken along the line III-III of the connector side support portion 14 shown in FIG. 5 and shows a cross section perpendicular to the predetermined axis X. FIG. 7 is a cross-sectional view taken along the line IV-IV of the cable side support portion 13 shown in FIG. 5 and shows a cross section perpendicular to the predetermined axis X. 6 also shows a plurality of built-in fibers 23, and FIG. 7 also shows a plurality of optical fibers F5.

  5 to 7 show an XYZ orthogonal coordinate system for easy understanding. The X axis included in this orthogonal coordinate system is an axis parallel to the predetermined axis X shown in FIGS. The Y axis is an axis that forms an XY plane parallel to the reference plane P1 (see FIGS. 6 and 7) including the predetermined axis X together with the X axis. The Z axis is an axis parallel to the normal of the reference plane P1.

  As shown in FIGS. 5 and 6, the connector-side support portion 14 includes two or more of the built-in fibers 23 that accommodate two or more (seven in the drawing) built-in fibers (first built-in fibers) 23 a. 2 (seven in the figure) accommodates two V-grooves (first grooves) 14a and two or more (six in the figure) built-in fibers (second built-in fibers) 23b among the plurality of built-in fibers 23. And more (six in the figure) V-grooves (second grooves) 14b. The V-groove 14a extends in the X-axis direction (that is, the direction along the predetermined axis X) and is formed side by side in the Y-axis direction. Similarly, the V-groove 14b extends in the X-axis direction and is formed side by side in the Y-axis direction.

  As shown in FIG. 6, the plurality of built-in fibers 23 are arranged by the V grooves 14a and 14b so that two rows along the reference plane P1 are aligned in a direction perpendicular to the reference plane P1. That is, the first built-in fiber 23a constitutes one fiber array and is arranged in one region A1 of the two regions A1 and A2 partitioned by the reference plane P1. The second built-in fiber 23b forms the other fiber array, and is arranged in the other region A2 of the two regions A1 and A2.

  Furthermore, the V-grooves 14a and the V-grooves 14b are alternately arranged when viewed from the Z-axis direction. The V groove 14a and the V groove 14b have a height difference h. More specifically, the V-groove 14a is arranged so that the bottom thereof overlaps the virtual plane P2 along the XY plane, and the V-groove 14b is arranged so that the bottom overlaps the virtual plane P3 along the XY plane. The virtual plane P2 and the virtual plane P3 are arranged in parallel to each other with a distance h. And the bottom part of V groove 14a and the bottom part of V groove 14b are arrange | positioned so that those Y-axis direction positions may mutually alternate.

  Thereby, the plurality of built-in fibers 23 are arranged so that the first built-in fibers 23a and the second built-in fibers 23b are alternately arranged when viewed from the direction perpendicular to the reference plane P1. In other words, the positions of the built-in fibers 23 in the direction along the reference plane P1 are alternately arranged with the built-in fibers 23a, the built-in fibers 23b, the built-in fibers 23a, the built-in fibers 23b,.

  Further, the end of the first built-in fiber 23a of the present embodiment is arranged side by side on a straight line La along the reference plane P1 in a cross section perpendicular to the predetermined axis X. Similarly, the end of the second built-in fiber 23b of the present embodiment is arranged side by side on a straight line Lb along the reference plane P1 in a cross section perpendicular to the predetermined axis X. Note that only one end of the first built-in fiber 23a and the second built-in fiber 23b may be arranged on a straight line along the reference plane P1.

  As shown in FIGS. 5 and 7, the cable-side support portion 13 includes two or more optical fibers (first optical fibers) F5a that accommodate two or more (seven in the drawing) of the plurality of optical fibers F5. 2 (seven in the figure) V-groove (third groove) 13a and two or more (six in the figure) optical fiber (second optical fiber) F5b among the plurality of optical fibers F5 are accommodated. And more (six in the figure) V-grooves (fourth grooves) 13b. The V-groove 13a extends in the X-axis direction (that is, the direction along the predetermined axis X) and is formed side by side in the Y-axis direction. Similarly, the V-groove 13b extends in the X-axis direction and is formed side by side in the Y-axis direction.

  As shown in FIG. 7, the plurality of optical fibers F5 are arranged by the V grooves 13a and 13b so that two rows along the reference plane P1 are aligned in a direction perpendicular to the reference plane P1. That is, the first optical fiber F5a constitutes one fiber array and is arranged in one region A1 of the two regions A1 and A2 partitioned by the reference plane P1. Further, the second optical fiber F5b constitutes the other fiber array, and is arranged in the other region A2 of the two regions A1 and A2.

  Furthermore, the V-grooves 13a and the V-grooves 13b are alternately arranged when viewed from the Z-axis direction. The V groove 13a and the V groove 13b have a height difference h. More specifically, the V-groove 13a is arranged so that the bottom thereof overlaps the virtual plane P4 along the XY plane, and the V-groove 13b is arranged so that the bottom overlaps the virtual plane P5 along the XY plane. The virtual plane P4 and the virtual plane P5 are arranged in parallel to each other with a distance h. And the bottom part of the V groove 13a and the bottom part of the V groove 13b are arrange | positioned so that those Y-axis direction positions may mutually alternate. The interval between the V grooves 13a is equal to the interval between the V grooves 14a in FIG. 6, and the interval between the V grooves 13b is equal to the interval between the V grooves 14b in FIG.

  Accordingly, the plurality of optical fibers F5 are arranged so that the first optical fibers F5a and the second optical fibers F5b are alternately arranged as viewed from the direction perpendicular to the reference plane P1. In other words, the positions of the optical fibers F5 in the direction along the reference plane P1 are alternately arranged with the optical fibers F5a, F5b, F5a, F5b,.

  Further, the end portion of the first optical fiber F5a of the present embodiment is arranged side by side on a straight line La along the reference plane P1 in a cross section perpendicular to the predetermined axis X. Similarly, the end portion of the second optical fiber F5b of the present embodiment is arranged side by side on a straight line Lb along the reference plane P1 in a cross section perpendicular to the predetermined axis X. Note that only one of the end portions of the first optical fiber F5a and the second optical fiber F5b may be arranged on a straight line along the reference plane P1.

  In the fusion splicer 1A according to this embodiment, the plurality of built-in fibers 23 and the plurality of optical fibers F5 are fusion-bonded to each other by the following method. That is, the first built-in fiber 23a is housed in the V-groove 14a, and the second built-in fiber 23b is housed in the V-groove 14b. In addition, the first optical fiber F5a is accommodated in the V groove 13a, and the second optical fiber F5b is accommodated in the V groove 13b. Then, the end of the first built-in fiber 23a and the end of the first optical fiber F5a are butted together in the gap 53, and at the same time, the end of the second built-in fiber 23b and the end of the second optical fiber F5b Are abutted against each other in the gap 53, and arc discharge by the pair of electrodes 15a and 15b of the discharge portion 15 is performed on the abutted portions. As a result, the plurality of built-in fibers 23 and the plurality of optical fibers F5 are fused and connected to each other.

  FIG. 8 is a diagram schematically showing the state of arc discharge, and shows a state seen from the X-axis direction. Arc discharge is a phenomenon that occurs between a pair of electrodes 15a and 15b arranged at both ends of the gap 53 in the Y-axis direction, and a discharge path A is generated between the electrodes 15a and 15b. The discharge path A has a shape in which the central portion swells in the space between the electrode 15a and the electrode 15b. Inside the region surrounded by the discharge path A, the ends of the plurality of built-in fibers 23 The ends of the plurality of optical fibers F5 are arranged. At the time of fusion, the temperature at the ends of these fibers 23 and F5 is, for example, 1000 degrees or more.

  Further, the position of the pair of electrodes 15a and 15b viewed from the X-axis direction is such that the line Lc connecting the pair of electrodes 15a and 15b is the first built-in fiber 23a and the first optical fiber F5a and the second built-in electrode. It may be determined to be positioned between the fiber 23b and the second optical fiber F5b.

  The effects of the fusion splicer 1A and the fusion splicing method described above will be described. As described above, in the fusion splicer 1A of the present embodiment, the V grooves 14a and 14b of the connector side support portion 14 support the plurality of built-in fibers 23 as follows. That is, the connector-side support portion 14 connects two or more first built-in fibers 23a among the plurality of built-in fibers 23 and the other two or more second built-in fibers 23b to both sides of the reference plane P1. (One area A1 and the other area A2). Then, the built-in fibers 23a and 23b are arranged so that the first built-in fibers 23a and the second built-in fibers 23b are alternately arranged as viewed from the direction perpendicular to the reference plane P1. Furthermore, the V-grooves 13 a and 13 b of the cable-side support portion 13 arrange a plurality of optical fibers F5 in the same manner as the built-in fiber 23. As a result, even when the optical fibers of the built-in fiber and the multi-core optical fiber cable are arranged in two rows, respectively, such as a 24-fiber MPO connector, a plurality of V-grooves 13a, 13b, 14a, and 14b are provided. The built-in fiber 23 and the optical fiber F5 can be easily positioned by the grooves.

  As described above, according to the fusion splicer 1A and the fusion splicing method of the present embodiment, the plurality of built-in fibers 23 and the optical fibers F5 arranged in two rows are divided into the plurality of V grooves 13a, 13b, 14a, and 14b. And can be easily positioned. Therefore, it is possible to easily perform fusion splicing between the plurality of built-in fibers 23 and the plurality of optical fibers F5.

  Also, as shown in FIG. 8, a line Lc connecting the pair of electrodes 15a and 15b is the first built-in fiber 23a and the first optical fiber F5a, the second built-in fiber 23b and the second light. The pair of electrodes 15a and 15b are preferably arranged so as to be positioned between the fibers F5b. Here, FIG. 9 is a diagram illustrating an example of a temperature distribution in arc discharge. In the figure, a region B1 is a region near the center of the arc discharge, a region B3 is a region near the outer periphery of the arc discharge, and a region B2 is a region between the region B1 and the region B3. Usually, the temperature increases in the order of the regions B3, B2, and B1. That is, in arc discharge, the temperature near the center of the current path tends to be the lowest, and the temperature near the outer periphery of the current path tends to be the highest. Therefore, by arranging the pair of electrodes 15a and 15b as described above, it is possible to suppress variations in the fusion temperature at each end of the plurality of built-in fibers 23 and the plurality of optical fibers F5.

  In this embodiment, the holder 30 shown in FIGS. 3 and 4 holds the ferrule of the multi-fiber optical connector and the plurality of built-in fibers 23, and this holder 30 is the holder of the fusion processing unit 10. A plurality of built-in fibers 23 are fixed to the fusion processing unit 10 by being mounted on the mounting unit 11. According to such a holder 30, if the connector plug 20 including the ferrule to which the built-in fiber 23 is attached in advance is placed in the holder 30, the holder 30 can cause the ferrule and the built-in fiber 23 to receive an impact from the outside. It is easy to handle at the time of delivery to the site and storage. In addition, since the holder 30 is mounted on the holder mounting portion 11 in a state in which the connector plug 20 is accommodated, the troublesome work of taking out the connector plug 20 from the holder 30 at the time of fusion connection becomes unnecessary, and the The handling property at the time of arrival and connection can be improved.

  Further, as shown in FIG. 4, a plurality of V grooves 33 for positioning and supporting the plurality of built-in fibers 23 are formed on the upper end surface of the front end wall 31b of the holder body 31 through which the built-in fibers 23 pass. ing. The plurality of V grooves 33 are also preferably formed in the same shape as the V grooves 14 a and 14 b of the connector side support portion 14. Thereby, since the built-in fiber 23 of the connector plug 20 accommodated in the holder 30 is accurately positioned by the V-groove 33, the positioning of the built-in fiber 23 is further facilitated when the holder 30 is attached to the fusion processing portion 10. can do.

  In the present embodiment, the holder 30 holds the connector plug 20 as described above, but the connector plug 20 including a plurality of built-in fibers 23 is positioned at the position of the holder mounting portion 11 of the fusion processing portion 10. It may be attached directly. Even if it is such a form, the effect by this embodiment mentioned above can be acquired suitably.

(Modification)
FIG. 10 is a view showing a cross section of the connector-side support 18 as a modification of the embodiment. FIG. 11 is a view showing a cross section of the cable-side support portion 17. These drawings show cross sections of the connector side support portion 18 and the cable side support portion 17 perpendicular to the predetermined axis X. In these drawings, a reference plane P1 including a predetermined axis X is shown. Further, FIG. 10 also shows a cross section of a plurality of built-in fibers 23, and FIG. A cross section of the fiber F5 is also shown.

  As shown in FIG. 10, the connector-side support 18 includes two or more (seven in the figure) V-grooves (first grooves) that accommodate two or more (seven in the figure) first built-in fibers 23a. ) 18a and two or more (six in the figure) V-grooves (second grooves) 18b for accommodating two or more (six in the figure) second built-in fibers 23b. Further, as shown in FIG. 11, the cable-side support portion 17 includes two or more (seven in the figure) V-grooves (firsts) that accommodate two or more (seven in the figure) first optical fibers F5a. ) 17a and two or more (six in the figure) V-grooves (second groove) 17b for accommodating two or more (six in the figure) second optical fibers F5b.

  As shown in FIGS. 10 and 11, the V-grooves 18a and 18b and the V-grooves 17a and 17b allow the plurality of built-in fibers 23 and the plurality of optical fibers F5 to have two rows along the reference plane P1 as a reference. They are arranged in a direction perpendicular to the plane P1. That is, the first built-in fiber 23a and the first optical fiber F5a constitute one fiber array, and are arranged in one region A1 of the two regions A1 and A2 partitioned by the reference plane P1. The second built-in fiber 23b and the second optical fiber F5b constitute the other fiber row, and are arranged in the other region A2 of the two regions A1 and A2.

  However, the first built-in fiber 23a and the first optical fiber F5a of this modification are arranged side by side on a curved line Ld that swells away from the reference plane P1 in a cross section perpendicular to the predetermined axis X. . Similarly, the second built-in fiber 23b and the second optical fiber F5b of this modification are arranged on a curved line Le that swells away from the reference plane P1 in a cross section perpendicular to the predetermined axis X. Be placed. Note that the arrangement of only one of the first built-in fiber 23a and the first optical fiber F5a and the second built-in fiber 23b and the second optical fiber F5b is away from the reference plane P1 in this way. It may be on a curved line that swells.

  By arranging the plurality of built-in fibers 23 and the plurality of optical fibers F5 as in this modification, the fusion of the built-in fibers 23 and the optical fibers F5 along the constant temperature region (see FIG. 9) in the arc discharge discharge path. Since a wearing part can be arrange | positioned, the dispersion | variation in the grade of a melt | fusion can be suppressed more effectively.

  The fusion splicer and the fusion splicing method according to the present invention are not limited to the above-described embodiments and modifications, and various other modifications are possible. For example, in the above embodiment and the modification, the configuration of the fusion splicer when the number of the built-in fibers and the number of the optical fibers of the multi-core optical fiber cable is 13 (7 in one row and 6 in the other row), respectively. Although illustrated, the number of built-in fibers in each row and the number of optical fibers of the multi-core optical fiber cable are not limited thereto.

DESCRIPTION OF SYMBOLS 1A ... Fusion splicer, 10 ... Fusion process part, 11 ... Holder mounting part, 12, 17 ... Cable mounting part, 13 ... Cable side support part, 13a, 13b, 14a, 14b ... V groove, 14, 18 ... Connector side support part, 15 ... discharge part, 15a, 15b ... electrode, 16 ... open / close cover, 20 ... connector plug, 21 ... plug frame, 22 ... stopper, 23 ... built-in fiber, 23a ... first built-in fiber, 23b ... 2nd built-in fiber, 24 ... dust cap, 30 ... holder, 31 ... holder main body, 31a ... plug accommodating part, 31b ... front end wall, 32 ... lid member, 32a ... rotation support shaft, 33 ... V groove, 53 ... gap A, discharge path, F1, multi-core optical fiber cable, F5, optical fiber, F5a, first optical fiber, F5b, second optical fiber, P1, reference plane, X, predetermined axis.

Claims (5)

The ends of a plurality of optical fibers of a multi-core optical fiber cable and the ends of a plurality of built-in fibers held by a ferrule of the multi-fiber optical connector with a direction along a predetermined axis as a longitudinal direction are fusion-bonded to each other. A fusion splicer that
Two or more first grooves that accommodate two or more of the plurality of built-in fibers (hereinafter referred to as first built-in fibers), and the other two or more of the plurality of built-in fibers A connector-side support portion having two or more second grooves for accommodating the built-in fiber (hereinafter, second built-in fiber)
Two or more third grooves for accommodating the optical fiber (hereinafter referred to as first optical fiber) fused to the first built-in fiber, and the optical fiber fused to the second built-in fiber (Hereinafter referred to as a second optical fiber) a cable-side support having two or more fourth grooves,
A discharge portion having a pair of electrodes for discharging in a space between the connector side support portion and the cable side support portion;
The first built-in fiber is disposed in one of the two regions partitioned by the reference plane including the predetermined axis, and the second built-in fiber is disposed in the other region, from the direction perpendicular to the reference plane. The first and second grooves are formed so that the first built-in fiber and the second built-in fiber are alternately arranged as seen.
The first optical fiber is disposed in the one area, the second optical fiber is disposed in the other area, and the first optical fiber and the second optical fiber are viewed from a direction perpendicular to the reference plane. The fusion splicer is characterized in that the third and fourth grooves are formed so that optical fibers are alternately arranged. Ends of at least one of the first built-in fiber and the second built-in fiber are arranged side by side on a straight line along the reference plane in a cross section perpendicular to the predetermined axis. The first and second grooves are formed;
The third and fourth grooves are formed such that end portions of the optical fiber fused to the at least one built-in fiber are arranged side by side on the straight line in a cross section perpendicular to the predetermined axis. The fusion splicer according to claim 1, wherein the fusion splicer is provided. The end of at least one of the first built-in fiber and the second built-in fiber is arranged side by side on a curved line that swells away from the reference plane in a cross section perpendicular to the predetermined axis. The first and second grooves are formed so that
The third and fourth grooves are formed such that end portions of the optical fiber fused to the at least one built-in fiber are arranged side by side on the curved line in a cross section perpendicular to the predetermined axis. The fusion splicer according to claim 1, wherein the fusion splicer is provided.   A line connecting the pair of electrodes when viewed from the direction of the predetermined axis is positioned between the first built-in fiber and the first optical fiber and the second built-in fiber and the second optical fiber. The fusion splicer according to any one of claims 1 to 3, wherein the pair of electrodes are arranged on a surface. The ends of a plurality of optical fibers of a multi-core optical fiber cable and the ends of a plurality of built-in fibers held by a ferrule of the multi-fiber optical connector with a direction along a predetermined axis as a longitudinal direction are fusion-bonded to each other. A way to
Two or more first grooves that accommodate two or more of the plurality of built-in fibers (hereinafter referred to as first built-in fibers), and the other two or more of the plurality of built-in fibers The first and second built-in fibers are inserted into the first and second grooves of the connector-side support portion having two or more second grooves for accommodating the built-in fibers (hereinafter referred to as second built-in fibers). Two or more third grooves that accommodate the optical fibers (hereinafter referred to as first optical fibers) that are respectively accommodated and fused to the first built-in fibers, and are fused to the second built-in fibers. The first and second optical fibers are inserted into the third and fourth grooves of the cable-side support portion having two or more fourth grooves that accommodate the optical fibers (hereinafter referred to as second optical fibers). Each accommodating step,
Fusing and connecting the end portions of the plurality of optical fibers and the end portions of the plurality of built-in fibers to each other by performing discharge in a space between the connector side support portion and the cable side support portion; With
In the first and second grooves, the first built-in fiber is disposed in one of two regions partitioned by a reference plane including the predetermined axis, and the second built-in fiber is disposed in the other region. Arranged so that the first built-in fiber and the second built-in fiber are alternately arranged as viewed from the direction perpendicular to the reference plane,
In the third and fourth grooves, the first optical fiber is disposed in the one region, the second optical fiber is disposed in the other region, and the third and fourth grooves are viewed from a direction perpendicular to the reference plane. The fusion splicing method, wherein the first optical fiber and the second optical fiber are formed so as to be alternately arranged.