JP2017111364A - Switching unit - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a switching unit which accurately and rapidly switches an active optical fiber to a bypass optical fiber.SOLUTION: In a switching unit, a magnet support part 90 in a latch state that movement of the magnet support part 90 is restricted by the latch mechanism, is in a position where a first magnet 91 and a flexure mechanism side magnet 15 are faced to each other while being energized by a spring 94, and a flexure mechanism support part 13 is given in which flexure parts 11, 12 are separated from flexure guide parts 21, 22 by magnetic force of the first magnet 91 and the flexure mechanism side magnet 15. The magnet support part 90, when the latch state by the latch mechanism is released, is moved by the energized force of the spring 94 to be a position where a second magnet 92 and the flexure mechanism side magnet 15 are faced to each other, and the flexure mechanism support part 13 is given in which the flexure parts 11, 12 are moved closer to the flexure guide parts 21, 22 by magnetic force of the second magnet 92 and the flexure mechanism side magnet 15.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a switching device.

  An optical fiber communication network using an optical fiber cable is widely used, and the end of the optical fiber transmission line constituting the communication network is a single optical fiber drawn into a user's house. In the current optical communication network, as is well known, from a base station to a user's house, first, a terminal box in which an optical transmission line composed of optical fiber cables bundled with a large number of optical fibers is installed in a power pole near the user's house. An optical fiber that is laid up to (closure) and branched into one in the closure is wired to each user's house.

  By the way, when maintenance or construction is carried out in the middle of an optical fiber transmission line upstream of a closure such as a base station close to the user's house, it is drawn into the user's house in the optical fiber transmission line. It is necessary to switch to the path of another optical fiber (hereinafter referred to as a bypass optical fiber) in the course of the path followed by one optical fiber (hereinafter referred to as the working optical fiber) so that the user can perform optical communication without any trouble. . That is, it is necessary to perform “short interruption switching” in which the switching work is performed in a very short time. An apparatus for performing the short break switching is called an “optical fiber short break switching apparatus”. The operating principle of the optical fiber short break switching device is described in, for example, Patent Document 1 below. In Patent Document 1, a predetermined amount or more of “bending” is compulsorily applied to an optical fiber that is an optical transmission line (active optical fiber here) at a portion that is desired to be blocked, and an optical fiber (active optical fiber) The light leaked from the bent part of the fiber is introduced into the opening end of the detour transmission line (here, the detouring optical fiber), or from the opening end of the detouring transmission line to the bent part of the optical fiber (the working optical fiber) An apparatus that performs short break switching operation by introducing light is disclosed.

Japanese Patent Laid-Open No. 2014-081491

  The optical fiber short break switching device is configured to bend the working optical fiber and guide light leaked from the bent position to the bypass optical fiber. For example, in the apparatus described in Patent Document 1, the working optical fiber is bent by sandwiching the working optical fiber between a cylindrical bent portion and an optical block having a concave portion that matches the outer diameter of the bent portion. The optical fiber short break switching device switches the active optical fiber that is a live line, that is, the active optical fiber that is in data communication, to the detour optical fiber, so that the optical communication path from the active optical fiber to the detour optical fiber is changed. It is necessary to prevent the end user from being aware that switching work or work for returning the switched communication path to the original state has been performed. However, the short break switching device is configured to perform a short break switching operation by manually operating a mechanical mechanism without using a power source. As a result, the accuracy and speed of the switching operation vary depending on the skill of the operator, the short interruption switching operation becomes uneven, and it is difficult to always provide the user with a stable data communication environment during the short interruption switching operation. It was.

  Therefore, according to the present invention, it is possible to switch the optical fiber of the working transmission line to the optical fiber of the bypass transmission line accurately and quickly, or return the switched communication path to the original state regardless of the skill of the operator. It is to provide a switching device.

A main invention for achieving the above object is a switching device that inputs and outputs an optical signal between the bent portion and the bypass optical fiber by bending the working optical fiber in the optical transmission line,
A bending portion and a bending guide for bending the working optical fiber; and a bending mechanism support portion to which the bending portion and a bending mechanism side magnet are fixed. The bending portion is moved by the movement of the bending mechanism support portion. A bending mechanism that moves relative to the bending guide;
A movable magnet support to which the first magnet and the second magnet are fixed;
A spring for biasing the magnet support portion;
A latch mechanism for restricting movement of the magnet support portion,
In the latch state in which the movement of the magnet support portion is restricted by the latch mechanism,
The magnet support portion is located at a position where the first magnet and the bending mechanism side magnet face each other in a state where a force is applied from the spring.
The bending mechanism support portion is located at a position where the bending portion is separated from the bending guide by the magnetic force of the first magnet and the bending mechanism side magnet,
When the latch state by the latch mechanism is released,
The magnet support portion is moved by the force urged from the spring and is in a position where the second magnet and the bending mechanism side magnet face each other.
The bending mechanism support portion is a switching device that moves the bending portion in a direction to approach the bending guide by the magnetic force of the second magnet and the bending mechanism side magnet.

  Other characteristics of the present invention will be made clear by the description and drawings described later.

  According to the switching device according to the present invention, the optical fiber of the working transmission line can be accurately and quickly switched to the optical fiber of the bypass transmission line regardless of the skill of the operator. Other effects will be clarified in the following description.

It is a figure for demonstrating the short interruption switch operation | movement in the switching apparatus (optical fiber short interruption switch 1) which concerns on the Example of this invention. 1 is an external view of an optical fiber short break switching device 1. FIG. It is a figure which shows the internal structure of the optical fiber short break switch 1. It is a figure when the operation | movement of the clamp guide 50 at the time of attaching the working optical fiber 200 to the optical fiber short break switching device 1 is seen from the front. It is a figure when the state in which the working optical fiber 200 is attached to the optical fiber short break switching device 1 is viewed from above. It is a figure which shows the operation procedure at the time of bending the working optical fiber 200 with which the optical fiber short break switching apparatus 1 was mounted | worn. It is a figure which shows the operation procedure at the time of returning the working optical fiber 200 in the bending state with which the optical fiber short break switching device 1 was mounted | worn to a linear state. It is a figure for demonstrating the structure of the clamp guide cancellation | release mechanism in the optical fiber short interruption device. It is a figure for demonstrating operation | movement of a clamp guide cancellation | release mechanism.

  At least the following matters will be apparent from the description and drawings described below.

  A switching device for inputting and outputting an optical signal between the bent portion and the detour optical fiber by bending the working optical fiber in the optical transmission line, the bending device for bending the working optical fiber And a bending mechanism supporting portion to which the bending portion and the bending mechanism side magnet are fixed, and the bending portion moves relative to the bending guide by the movement of the bending mechanism supporting portion. A movable magnet support portion to which the first magnet and the second magnet are fixed, a spring for biasing the magnet support portion, and a latch mechanism for restricting the movement of the magnet support portion. In the latched state in which the movement of the magnet support portion is restricted by a mechanism, the magnet support portion is in a state where a force is urged from the spring. The first magnet and the bending mechanism side magnet are in a position facing each other, and the bending mechanism support portion is located at a position where the bending portion is separated from the bending guide by the magnetic force of the first magnet and the bending mechanism side magnet. And when the latched state by the latch mechanism is released, the magnet support portion is moved by the force urged by the spring, and the second magnet and the bending mechanism side magnet face each other. The switching device is characterized in that the bending mechanism support portion moves in a direction in which the bending portion approaches the bending guide by the magnetic force of the second magnet and the bending mechanism side magnet. According to the above switching device, it is possible to bend the working optical fiber that is the target of short break switching instantaneously and accurately regardless of the skill of the operator.

  The magnet support portion includes a pressing member that is pressed by an operator. When the pressing member is pressed when the second magnet and the bending mechanism side magnet are opposed to each other, the magnet support portion is provided. The portion is in a position where the first magnet and the bending mechanism side magnet face each other in a state where a force is urged from the spring, and the bending mechanism support portion is formed by the first magnet and the bending mechanism side magnet. It is preferable that the bending portion is separated from the bending guide by a magnetic force, and the latch mechanism is in the latched state in which movement of the magnet support portion is restricted in a state where force is urged from the spring. Thus, if an operation for releasing the bent working optical fiber 200 to a linear state is performed, it is possible to prepare for the next switching operation naturally.

  The latch mechanism includes a lever and a lever spring, and the lever can regulate the movement of the magnet support portion by engaging with the pressing member, and can be controlled by operating the lever. The lever is disengaged from the pressing member, the latched state is released, the pressing member is pressed, and the magnet support portion faces the first magnet and the bending mechanism side magnet. The lever is preferably engaged with the pressing member by the urging force of the lever spring when the position is reached. As a result, it is possible to naturally return to the latched state and prepare for the next switching operation.

  A clamp base and a clamp guide for sandwiching the working optical fiber; and a clamp guide release mechanism for opening the clamp guide in conjunction with the pressing member being pressed, the clamp guide being a clamp guide When the working optical fiber is sandwiched between the clamping base and the pressing member by a biasing force of the spring, and the pressing member is pressed from a predetermined position where the bending portion and the bending guide are separated from each other, the clamp guide It is preferable that the clamp guide is opened by a release mechanism, and the working optical fiber is released from a state of being sandwiched between the clamp base and the clamp guide. Thereby, it can suppress that the working optical fiber falls out of a bending part, before a bending part leaves | separates from a bending guide.

  The clamp guide release mechanism includes a first contact portion that contacts the magnet support portion and a second contact portion that contacts the clamp guide, and the pressing member is pressed from the predetermined position. Then, when the magnet support portion presses the first contact portion, the clamp guide release mechanism rotates, and the second contact portion urges the clamp guide in an open state. Is desirable. Accordingly, the clamp guide can be opened against the biasing force of the clamp guide spring that biases the clamp guide in the closing direction.

  The three directions perpendicular to each other are defined as the front-rear direction, the up-down direction, and the left-right direction. A box-shaped housing that is flat in the left-right direction, the distal end side of the pressing member projects from the rear end of the housing and extends forward toward the proximal end side, and the lever extends from the rear end surface of the housing. If it is a switching device that is led out to the outside and tilts in the left-right direction, a plurality of optical fiber short break switching devices are arranged in parallel in the left-right direction in one closure. It can also be installed in a place where a large work space cannot be secured in the left-right direction. In other words, even if there is no wide work space in the left-right direction, the operator can easily perform the short break switching operation.

=== Configuration and structure of optical fiber short break switching device ===
As an example of the switching device according to the present invention, an optical fiber short interruption switching device (hereinafter referred to as a short interruption switching device) will be given and described with reference to the accompanying drawings. Note that in the drawings used for the following description, the same or similar parts may be denoted by the same reference numerals and redundant description may be omitted. In some drawings, reference numerals may be assigned to parts that are not required in other drawings if unnecessary.

<Principle of short break switching>
FIG. 1 is a schematic view showing a bending operation of the working optical fiber 200 by the short break switching device 1 according to the embodiment of the present invention. FIGS. 1A and 1B show states before and after the working optical fiber 200 is bent. Here, it is assumed that one optical fiber drawn from the short break switching device 1 to the user's home side is laid downstream. Further, as shown in the figure, the working optical fiber 200 extending in the upstream / downstream direction in the short break switching device 1 is defined with the downstream side as the rear side and the upstream side as the front side, and the working optical fiber is defined. The vertical direction is defined as bending 200 downward. In addition, the front and back direction of the paper surface in FIG. That is, FIG. 1 shows a view of the surface including the front-rear and up-down directions from the right. In FIG. 1 and the drawings shown below, the above-described front-rear, left-right, up-down, up-down directions, and upstream-downstream relationships are also employed.

  The short break switching device 1 includes a mechanism for bending the working optical fiber 200 by pressing a part of the working optical fiber 200 downward (hereinafter referred to as a bending mechanism 10), and a working optical fiber pressed downward by the bending mechanism 10. 200 has a mechanism (hereinafter referred to as a bending guide mechanism 20) that guides 200 so as to have a predetermined bent shape. In the present embodiment, the bending mechanism 10 protrudes toward the right with the left end as a base, and the tip end side is formed in a columnar shape, and the bend mechanism 10 is disposed upstream of the detour bend portion 11. Similar to the bypass bending portion 11, the loss application bending portion 12 whose front end protrudes in a columnar shape, and the bypass bending portion and the loss application bending portion are attached side by side in the front-rear direction while extending in the vertical direction. And a bending mechanism support portion 13. The bending guide mechanism 20 includes a bypass bending guide portion 21 having a recess 23 formed in an arc shape whose bottom surface engages with a side surface circumferential shape of a cylindrical portion of the bypass bending portion 11, and a loss applying bending portion 12. And a loss-applying bending guide portion 22 having a concave portion 24 having an arc-shaped bottom surface that engages with the circumferential shape of the side surface of the cylindrical portion. The bending guide mechanism 20 has a thick plate shape with the left-right direction being the thickness direction, and the bending mechanism 10 is configured to move downward from above with respect to the bending guide mechanism 20. The bypass bending guide portion 21 is formed of a transparent resin, and a downstream end (hereinafter referred to as an open end) of the bypass optical fiber 210 is placed on a curved tangent line 25 continuous from the front of the upper end to the arc-shaped bottom surface. 211) is open. The bypass optical fiber 210 is led along the extension of the tangent line 25 in the short break switching device 1 and gently bent backward along the way, and is led out of the short break switching device 1.

  As the bending operation of the working optical fiber 200 by the short break switching device 1 according to the present embodiment, first, as shown in FIG. 1A, the recesses of the bypass bending guide portion 21 and the loss applying bending guide portion 22 (see FIG. 23, 24), the working optical fiber 200 is bridged. As shown in FIG. 1 (B), the bypass bending portion 11 and the loss applying bending portion 12 (hereinafter sometimes collectively referred to as “bending portions (11, 12)”) As 13 is moved downward, it abuts against the upper edge of the working optical fiber 200 extending in the front-rear direction and pushes it downward. As a result, the working optical fiber 200 is bent while being sandwiched between the bypass bending portion 11 and the bypass bending guide portion 21 and between the loss applying bending portion 12 and the loss applying bending guide portion 22. When the working optical fiber 200 is bent as described above, the light propagating from the downstream side in the working optical fiber 200 leaks from the portion 201 bent by the bypass bending portion 11 and the bypass bending guide portion 21, and the leakage. Light enters the open end 211 of the bypass optical fiber 210. Further, the light propagating through the bypass optical fiber 210 from the upstream to the downstream exits from the opening end 211 of the bypass optical fiber 210 and enters the bent portion 201 of the work optical fiber 200 to enter the work optical fiber 200. Propagate downstream of As a result, an optical communication path is formed between the downstream end of the working optical fiber 200 and the optical transmission path connected to the upstream side of the bypass optical fiber 210. The loss application bending portion 12 and the loss application bending guide portion 22 are not slightly leaked by the downstream bypass bending portion 11 and the bypass bending guide portion 21 because all of the light propagating through the working optical fiber 200 is not leaked. In this case, the current optical fiber 200 is bent again to block the leaked light and prevent any light from propagating upstream.

<Appearance>
FIG. 2 is a diagram illustrating an appearance of the short break switching device 1 according to the present embodiment. In this figure, a case where four short break switching devices 1 of the same type are arranged in parallel in the left-right direction is taken as an example. In this example, the four short break switching devices 1 are arranged in parallel by being attached to the base 300 whose lower end surface 31 is fixed in the closure. Here, the appearance of the short interruption switching device 1 will be described mainly using the reference numerals attached to the short interruption switching devices 1 arranged at both left and right ends. The short interruption switching device 1 is a flat box in the left-right direction. The above-described bending mechanism 10, the bending guide mechanism (reference numeral 20 in FIG. 1), and the bending mechanism are moved in the vertical direction inside the casing 30 that forms the exterior of the short break switching device 1 The mechanism for making it accommodate is accommodated. Further, at the lower end of the front end face 32, the leaked light incident on the bypass optical fiber (FIG. 1, reference numeral 210) from the working optical fiber (FIG. 1, reference numeral 200) inside the housing 30 is condensed and bypassed. An optical fiber probe 220 for leading to a transmission line is connected.

  The casing 30 is generally a box shape that is flat on the left and right, but the front-rear width on the lower side is wider than the front-rear width on the upper side. The front and rear end faces (32, 33) are formed with slopes (34, 35) for connecting a flat box-like lower region widened in the front-rear direction and an upper region reduced in the front-rear direction. The front end face 32 and the rear end face 33 are displaced in the vertical direction from the formation position of the inclined surfaces (34, 35) depending on the shape of the internal structure. A rectangular opening 37 is formed on the right side 36 side of the upper region of the housing 30. Further, the left and right widths of the upper region on the upper side and the lower side are different, the width w on the upper side is smaller than the width W on the lower side, and the right edge of the opening 37 is on the way from the upper side to the lower side. After bending in an L shape to the right, it bends downward and reaches the front and rear ends of the lower edge of the opening 37. The left side surface 38 of the housing 30 is continuous with the front and rear end surfaces (32, 33) at both front and rear edges. The upper end surface 39 of the housing 30 has the original left-right width W of the housing 30 and covers the upper part of the bending mechanism 10, and the front and rear ends of the upper end surface 39 gradually widen in the front-rear direction downward. However, the upper end portions of the front and rear end surfaces (32, 33) reduced to the width w are connected via a smooth continuous surface 40. Accordingly, the upper end side of the housing 30 is formed in a bowl shape by the continuous surface 40 and the upper end surface 39.

  A rectangular flat plate-shaped clamp guide 50 is disposed in a region where the opening 37 is formed on the right side surface 36 of the housing 30. The clamp guide 50 maintains the front-rear width of the opening 37 of the housing 30 and covers from the lower edge of the opening 37 to the lower end of the continuous surface 40, that is, the upper end positions of the front and rear end surfaces (32, 33). In the shape region, the opening 37 is not closed by the clamp guide 50, and when the bending mechanism 10 is in the upward movement position, the bent portions (11, 12) are exposed at the upper portion of the opening 37. The upper end 51 of the clamp guide 50 is formed in a smooth curved surface so as to protrude upward when viewed from the front-rear direction, and the upper end 51 is separated from the right end of the bent portions (11, 12) (also in FIG. 4). reference). The upper end 51 of the clamp guide 50 is also spaced apart from the internal structure in the housing 30 due to the curved surface shape, so that a groove shape extending in the front-rear direction is opened between the internal structure and the upper end 51 while opening upward. A gap 41 is formed.

  Further, since it is assumed that the short break switching device 1 of the present embodiment is arranged in parallel in the left-right direction, it is necessary to provide an operation system required for the short break switching operation on the front and rear end faces (32, 33). is there. In the present embodiment, a lever 60 that extends upward is led out to a slope 35 that continues upward and downward on the rear end surface 33, and a knob 61 is attached to the upper end of the lever 60. On the rear end surface 33 of the housing 30, a columnar member (hereinafter referred to as a pressing member 70) with the front-rear direction as an axis protrudes rearward in a region continuous below the slope 35 from which the lever 60 is led out. Yes. Then, the short break switching device 1 tilts the lever 60 in the direction of the arrow (right direction) attached to the characters “CLANMP” written on the rear end surface 33 or the right side surface 36 of the housing 30 or “OPEN”. The bending mechanism 10 housed in the housing 30 can be moved up and down by pressing the pressing member 70 in the direction of the arrow (forward direction) attached to the character.

<Internal structure>
FIG. 3 is a diagram showing a structure 1i inside the housing in the short break switching device of the present embodiment. 3A is a perspective view of the internal structure 1i as viewed from the upper right rear, and FIG. 3B is an exploded view of some members such as the clamp guide 50 from the internal structure 1i shown in FIG. It is a perspective view which shows the state which carried out. FIG. 3C shows the left side (hereinafter, back side) of the clamp guide 50. Hereinafter, the internal structure 1i of the short break switching device according to the present embodiment will be described with reference to FIGS. Various movable mechanisms included in the internal structure 1i of the housing are attached to the base 80, the inner surface of the housing, and the like. The bending mechanism 10 includes a bending mechanism support portion 13 that can move in the vertical direction, and bending portions (11, 12) attached to the upper end of the bending mechanism support portion 13. The bending mechanism support portion 13 has a region 14 protruding rightward in a block shape at the lower end thereof, and permanent magnets (hereinafter referred to as a bending mechanism side magnet 15) having different magnetic poles in the vertical direction are embedded in the protruding region 14. It is. Further, the lower end of the base 80 is cut into a rectangular shape so as to open downward, and the bending mechanism support portion 13 extends along the left surface 81 of the base 80 and protrudes from the lower end (hereinafter referred to as a bending mechanism side magnet support portion). 14) is exposed to the right through a notch formed in the lower end of the base 80. And the bending mechanism side magnet support part 14 can move to the up-down direction within the formation area of the notch part of this base 80. As shown in FIG. Thereby, the entire bending mechanism 10 can be moved in the vertical direction. As described above, the bending portions (11, 12) are formed to protrude rightward at the upper end of the bending mechanism support portion 13, and the right end side has a cylindrical shape. Further, a groove 14 is formed around the side surface of the cylindrical portion. The right end surfaces of the bending portions (11, 12) are the right ends of the bypass bending guide portion 21 and the loss applying bending guide portion 22 (hereinafter sometimes collectively referred to as “bending guide portions (21, 22)”). It protrudes further to the right than the surface 26.

  The bending guide mechanism 20 is formed integrally with the plate-like bending guide portions (21, 22) attached to the right surface of the base 80 and the base 80, and is arranged side by side in the front-rear direction while protruding rightward. It is comprised from the 1st-3rd clamp stand (82-84) which is. The first to third clamp bases (82 to 84) are separated from each other in the front-rear direction, and slits that open both the upper and lower ends and the right side between adjacent clamp bases in the front-rear direction (82-83, 83-84). 86 is formed, and the bent portions (11, 12) move in the vertical direction in the slit 86. Further, the right end surface 85 of the first to third clamp stands (82 to 84) is retracted to the left from the right end surface 26 of the bending guide portion (21, 22), and is mounted in the short break switching device. The working optical fiber is restricted to move to the left by contacting the right end face 85 of the first to third clamp stands (82 to 84).

  A magnet operating mechanism for moving the bending mechanism 10 in the vertical direction by applying a magnetic force from other permanent magnets (91, 92) to the bending mechanism side magnet 15 is also incorporated in the casing. The magnet operation mechanism includes a columnar pressing member 70 and a lever 60 that are led rearwardly out of the housing 30 in FIG. 2, and the pressing member 70 has a groove 71 along the circumferential direction on the rear end side. And the front end is connected to a block-shaped member 90 inside the housing. Two permanent magnets (91, 92) whose vertical direction is the magnetic pole direction are embedded side by side in the front-rear direction in a block-shaped member 90 connected to the front end of the pressing member 70. The two permanent magnets (91, 92) have one magnetic pole exposed at an upper end surface 93 of a block-like member (hereinafter referred to as a magnet support portion 90), and the two permanent magnets exposed at the upper end surface 93 ( The magnetic poles 91 and 92) are in opposite directions. The rear magnet (hereinafter referred to as the first operating mechanism side magnet 91) is the same polarity as the magnetic pole on the lower surface side of the bending mechanism side magnet 15 described above, and repulsive when both magnets (15, 91) are facing each other. As a result, the bending mechanism 10 is kept pushed upward. The front magnet (hereinafter referred to as the second operating mechanism side magnet 92) has a different polarity from the magnetic pole on the lower surface side of the bending mechanism side magnet 15, and when both the magnets (15, 92) face each other, the attractive force Thus, the bending mechanism 10 is maintained in a state where it is pulled downward. That is, as the pressing member 70 moves in the front-rear direction, the bending mechanism 10 moves in the vertical direction by causing the bending mechanism-side magnet 15 to face either the first operating mechanism-side magnet 91 or the second operating mechanism-side magnet 92. Then, the short-time interruption switching operation is executed by bending the working optical fiber mounted in the short-time interruption switching device or returning the bent optical fiber to the linear state.

  More specifically, the mechanism related to the short break switching operation will be described in detail. The rear end of the magnet support portion 90 is in contact with the rear end of a coil spring (hereinafter referred to as a magnet operation spring 94) centering on the front-rear direction. Yes. The front end of the magnet operating spring 94 is fixed to the housing. In FIG. 2, the lever 60 led upward from the rear end surface 33 of the housing 30 has a plate-like shape extending parallel to the rear end surface 33 of the housing 30 and extending vertically. The upper end side and the lower end side are swung in the left and right directions with a shaft (hereinafter referred to as a lever shaft 62) extending in the front-rear direction as a fulcrum. The bearing is formed on the inner surface of the housing. A notch 63 that engages with the groove 71 of the pressing member 70 is formed on the right edge below the lever shaft 62. Further, the lower end of the lever 60 is formed in a flat plate shape that is bent forward and has both front and back surfaces in the left-right direction, and a coil spring (hereinafter referred to as a lever spring 65) having the left-right direction as an axis on the left surface of the flat plate portion 64 The lever spring 65 urges the lower end side of the lever 60 to the right. Accordingly, when the notch 63 of the lever 60 is engaged with the groove 71 of the pressing member 70, the lever 60 maintains that state, and accordingly, the pressing member 70 maintains the state of being pushed forward. At this time, the magnet operating spring 94 is compressed. In this state, the bending mechanism side magnet 15 and the first operating mechanism side magnet 91 face each other with the same polarity, and the bending mechanism 10 maintains a state of moving upward.

  On the other hand, when the lever 61 is operated to the right by operating the knob 61 of the lever 60, the engagement state between the notch 63 of the lever 60 and the groove 71 of the pressing member 70 is released, and the magnet is in a compressed state. The spring 94 pushes the magnet support portion 90 backward. Accordingly, the bending mechanism side magnet 15 and the second operation mechanism side magnet 92 face each other with different polarities, and the bending mechanism 10 moves downward. At this time, if the working optical fiber is attached, the working optical fiber is sandwiched and bent between the bent portions (11, 12) and the bending guide portions (21, 22), and bypasses the working optical fiber. An optical communication path is formed between the optical fibers.

  A clamp guide 50 is also attached to the base 80. A shaft hole 53 that protrudes in the form of a tongue toward the left while sharing a part of the end face 52 and that penetrates forward and backward is provided slightly below the center of the upper and lower end faces 52 of the clamp guide 50. A bearing portion 54 is formed. A shaft (hereinafter referred to as a clamp guide shaft 87) inserted through the shaft hole 53 is formed on both front and rear end surfaces of the base 80 so as to protrude forward and rearward. A coil spring (hereinafter referred to as a clamp guide spring 57) attached to the right end surface of the base 80 with the left and right direction as an axis is located in a region 55 below the shaft hole 53 on the left surface (hereinafter referred to as a back surface 56) of the clamp guide 50. ) Is in contact, and the region below the shaft hole is urged to the right. That is, in the clamp guide 50 in a steady state where no external force is applied, a region 58 above the shaft 53 on the back surface 56 is urged to the left. Therefore, if the working optical fiber is mounted in the short break switching device, the working optical fiber is located between the back surface 56 of the clamp guide 50 and the right end surface 85 of the first to third clamp stands (82 to 84). The deviation from the predetermined position is suppressed. Further, as shown in FIG. 3C, the clamp guide 50 is formed in a thin plate shape in which the front and rear end faces 52 are continuous with the bearing portion 54, and the back face 56 is formed with three plates from the upper end downward. Two short ribs 59 are also formed. The shape of the rib 59 when viewed from the front-rear direction is the same as the shape of the upper left end of the front-rear both end surfaces 52 of the clamp guide 50. It is extended toward. The formation position of the rib 59 in the front-rear direction does not overlap with the formation area in the front-rear direction of the bent portions (11, 12). When the clamp guide 50 is in a steady state, the left edge of the rib 59 and the front and rear end faces 52 is the right end of the first to third clamp bases (82 to 84) by the urging force of the clamp guide spring 57. It is in contact with the surface 85. In this embodiment, an area (hereinafter referred to as a clamp guide protrusion 101) protruding downward in a rectangular shape is formed on the front side of the lower end of the clamp guide 50, and this clamp guide protrusion 101 is a clamp guide release which will be described later. It is a component of the mechanism.

=== Procedure for short break switching operation and operation of short break switching device ===
Next, the operation of the apparatus will be described while following the procedure of the step instantaneous interruption switching operation using the short interruption switching apparatus according to the present embodiment.

<Installation of working optical fiber>
As described above, the short interruption switching device of the present embodiment assumes that a plurality of units are arranged in parallel at narrow intervals in the left-right direction. For this reason, it is difficult to mount the working optical fiber in the short interruption switching device from the left and right directions except for the short interruption switching device arranged at the right end. Therefore, in the short break switching device of the present embodiment, the working optical fiber extending in the front-rear direction having the characteristics of the shape and opening / closing structure of the clamp guide and the shape of the upper end surface of the casing is switched from the top to the short break. It is guided in the apparatus and is naturally mounted at a predetermined position.

  FIGS. 4 and 5 show enlarged views of the upper part of the short break switching device 1. FIG. 4 is a view when the upper part of the short break switching device 1 is viewed from the front. FIGS. 4A and 4B show a state before the working optical fiber 200 is attached to the short break switching device 1. And after wearing. FIG. 5 is a view of the internal structure 1i of the short break switching device 1 as viewed from above, and shows a state in which the working optical fiber 200 is attached. Hereinafter, the installation procedure of the working optical fiber 200 will be described with reference to FIGS. 4 and 5.

  As shown in FIG. 4A, in the steady state before the working optical fiber 200 is mounted, the left edge of the front and rear end faces 52 of the clamp guide 50 and the left edge of the rib 59 are the first to third clamps. It abuts against the right end surface 85 of the base (hereinafter also referred to as “clamp base (82 to 84)”). As described above, the upper end 51 of the clamp guide 50 is formed with a smooth curved surface so that the working optical fiber 200 is not damaged when the working optical fiber 200 is guided from the top to the bottom in the short break switching device 1. . The upper end surface 39 of the housing 30 is formed in a bowl shape covering the bent portions (11, 12) protruding rightward. Further, the right edge 42 of the bowl-shaped region formed by the upper end surface 39 and the inclined surfaces 40 extending downward at the front and rear ends thereof has a lateral width W of the upper end surface 39 downward when viewed from the front-rear direction. It is continuous so as to be smoothly reduced to the width w. Accordingly, the working optical fiber 200 is inserted into these bent portions (11, 12) when inserted into the short break switching device 1 from above to below while maintaining the working optical fiber 200 to extend in the front-rear direction. It won't get caught.

  In order to attach the working optical fiber 200 to a predetermined position in the short break switching device 1, the working optical fiber 200 is moved further downward so that the working optical fiber 200 is connected to the upper end 51 of the clamp guide 50. When inserted into the short break switching device through the groove-like gap 41 formed between the right edge end 42 of the above-mentioned bowl-shaped region forming the upper end portion of the opening 37 of the housing 30, the housing The working optical fiber 200 is smoothly guided into the short interruption switching device 1 by the smooth shape at the right edge 42 of the inclined surface 40 continuing from the upper end surface 39 of the front and rear ends (32, 33). The working fiber 200 inserted into the groove-shaped gap 42 is interrupted between the clamp table (82 to 84) and the clamp guide 50 from the upper end of the clamp guide 50, and the upper end 51 side of the clamp guide 50 is the side of the working optical fiber 200. It will open slightly to the right by the thickness. At this time, since the upper end 51 side of the clamp guide 50 is urged to the left by the clamp guide spring 57 that is in contact with the back surface 56 of the lower region 55 of the clamp guide 50, both front and rear end faces 52 of the clamp guide 50 are provided. Or between the rib 59 and the clamp base (82 to 84). Further, since the clamp guide 50 is urged to the left by the clamp guide spring 57, the working optical fiber 200 is maintained between the clamp guide 50 and the clamp base (82 to 84). However, it is inserted to the upper end position of the bending guide part (21, 22). As a result, as shown in FIGS. 4B and 5, the working optical fiber 200 includes the clamp guide spring 57 between the bent portions (11, 12) and the bent guide portions (21, 22). Due to the urging force, the clamp guide 50 is held between the back surface 56 and the clamp base (82 to 84).

If the working optical fiber 200 mounted in the short break switching device 1 is in a straight state without being bent, the working light is interposed between the clamp guide 50 and the clamp base (82 to 84). The active optical fiber 200 can be moved upward while maintaining the state where the fiber 200 is held, and the active optical fiber 200 can be easily taken out.
As described above, according to the short break switching device 1 of the present embodiment, when installing the working optical fiber 200, it is not necessary to open the clamp guide 50 widely in the left-right direction, and the working optical fiber 200 is extended in the front-rear direction. It is possible to mount it naturally at a predetermined position simply by moving it downward while matching it. Moreover, the working optical fiber 200 can be taken out from each short interruption switch 1 only by moving the installed working optical fiber 200 upward while making the extension direction coincide with the front-rear direction. In particular, as shown in FIG. 2, when a plurality of short break switching devices 1 are arranged in parallel in the left-right direction, the installation and removal of the working optical fiber 200 becomes easier at each stage than before. Of course, the short break switching device 1 of the present embodiment does not require a high level of skill when the working optical fiber 200 is attached or removed.

<Short break switching operation>
Next, an operation procedure for bending the working optical fiber mounted at a predetermined position in the short break switching device and an operation of the short break switching device according to the procedure will be described. FIG. 6 shows an operation state in the short break switching device when the working optical fiber in a straight state is bent. The operation procedure for bending the working optical fiber in the order of FIGS. 6 (A) to 6 (C) and the states of various mechanisms in the short break switching device in each procedure are shown. Here, the internal structure 1i in which the base is omitted is shown. First, as shown in FIG. 6A, first, the working fiber 200 is stretched over the upper ends of the bending guide portions (21, 22). The lever 60 is latched by the notch 63 formed at the lower end engaging the groove 71 of the pressing member 70. That is, the backward movement of the pressing member 70 and the magnet support portion 90 connected to the front end thereof by the magnet operating spring 94 is restricted. In this state, the first operating mechanism side magnet 91 embedded in the magnet support 90 faces the bending mechanism side magnet 15, and the bending mechanism 10 moves upward by the repulsive force between the two magnets (92-15). It is held in the state.

  Next, as shown in FIG. 6B, when the lever 60 is tilted rightward to release the latch, the magnet support 90 is pushed backward by the restoring force of the magnet operating spring 94. Then, as shown in FIG. 6C, the magnet support 90 moves instantaneously rearward as the latch is released, and the second operating mechanism side magnet 92 faces the bending mechanism side magnet 15. Thereby, an attractive force acts between both magnets (93-15), the bending mechanism 10 moves downward, and the bending portions (11, 12) push the working optical fiber 200 downward. At this time, since the upper surface side of the working optical fiber 200 is inscribed in the groove 14 formed on the side surface of the cylindrical portion on the right end side of the bent portions (11, 12), the working optical fiber 200 is pushed downward at an extremely high speed. However, it does not deviate to the right. The working optical fiber 200 is sandwiched between the bent portions (11, 12) and the bending guide portions (21, 22), and an optical transmission path is formed between the working optical fiber 200 and the bypass optical fiber 210. The

  Next, when the optical transmission line between the working optical fiber 200 and the detouring optical fiber is cut off and returned to the original optical transmission line of only the working optical fiber, the order of FIGS. 6A to 6C is performed. The working optical fiber 200 in the bent state may be returned to the linear state so as to be opposite to the operation shown. FIG. 7 shows the return operation of the working optical fiber 200 in the short break switching device. The operation procedure for returning the working optical fiber 200 in the order of FIGS. 7A to 7C and the states of various mechanisms in the short interruption switching device in each procedure are shown. As shown in FIG. 7A, when the latch of the pressing member 70 is released and the pressing member 70 protrudes backward, the bending mechanism (11, 12) is in the lower position and the working optical fiber. 200 is bent. Next, as shown in FIG. 7B, when the pressing member 70 is pressed forward to move the magnet support portion 90 forward, the first operating mechanism side magnet 91 and the bending mechanism side magnet 15 are moved. A repulsive force is generated in both magnets (92-15) facing each other. Further, the lever 60 has a flat plate portion 64 at the lower end urged to the right by a region including the notch 63 below the lever shaft 62 by the urging force of the lever spring, so that the pressing member 70 is pressed to a predetermined position. Then, the notch 63 of the lever 60 is engaged with the groove 71 of the pressing member 70, and the pressing member 70 is latched. Then, as shown in FIG. 7C, the bending mechanism 10 is pushed upward by the repulsive force between the first operating mechanism side magnet 91 and the bending mechanism side magnet 15, and the bending portions (11, 12) and the bending guide are moved. The engagement with the portion (21, 22) is released, and the working optical fiber 200 returns to the original linear state.

  Thus, according to the short break switching device of the present embodiment, the latch of the pressing member 70 is released in conjunction with the operation of the lever 60, or the pressing member 70 that is pushed in using the biasing force of the lever 60 is released. The short break switching operation is executed instantaneously and accurately with only a simple operation such as automatic latching. Of course, these operations do not require high skill.

<Removal of working optical fiber>
In the short break switching device of the present embodiment, the working optical fiber mounted in a straight state can be taken out simply by moving upward. However, in the short break switching device of the present embodiment, in order to further facilitate this take-out operation, a clamp guide protrusion (formed on the lower end of the clamp guide in conjunction with the operation of pressing the pressing member forward ( 3 is provided with a dedicated mechanism that can keep the clamp guide open by urging the reference numeral 101) to the left. This mechanism is the above-described clamp guide release mechanism. FIG. 8 is a diagram for explaining the structure of the clamp guide releasing mechanism, and here, a perspective view of the internal structure 1i of the short break switching device with the base omitted is viewed from the upper right front. As shown in FIG. 8, on the front end side of the internal structure 1i, a plate-like member (hereinafter referred to as clamp guide release) that is pivotally supported by a shaft extending in the vertical direction (hereinafter referred to as clamp guide release mechanism shaft 102). A plate 100) is attached. The clamp guide release plate 100 has a plate-like portion on the left side (hereinafter referred to as release action plate 103) extending downward with respect to the clamp guide release mechanism shaft 102, and the release action plate 103 contacts the front end of the magnet support portion 90. It is configured to touch. A plate-like portion on the right side with respect to the clamp guide release mechanism shaft 102 (hereinafter referred to as clamp guide pressing plate 104) is directed rearward so as to be perpendicular to the plate surface of the release action plate 103 while being spaced above the magnet support 90. The left surface is in contact with the right surface of the clamp guide protrusion 101.

  FIG. 9 shows a view of the main part of the clamp guide releasing mechanism as viewed from above. FIGS. 9A and 9B show the state of the clamp guide release plate 100 before and after the working optical fiber 200 is taken out. Hereinafter, the operation of the clamp guide release mechanism will be described in the order of FIGS. 9A and 9B with reference to FIG.

  First, as shown in FIG. 9A, when the pressing member 70 is pushed in and the pressing member 70 is latched, the clamp guide 50 is in a steady state, and the clamp guide pressing plate 104 is extended in the front-rear direction. Is maintained. When the pressing member 70 is pushed deeply forward, the front end of the magnet support portion 90 presses the release action plate 103 rearward, and the clamp guide release plate 100 is released from the clamp guide when viewed from above as shown in FIG. 9B. It rotates clockwise around the mechanism shaft 102. Along with this, the clamp pressing plate 104 presses the clamp guide protrusion 101 in the clamp guide 50 toward the left, and the upper region 58 of the clamp guide 50 opens to the right.

  In addition, the working optical fiber in the bent state immediately returns to the linear state at the same time as the regulating force for bending itself disappears, and is urged upward by the reaction caused by the return. Therefore, if the pressing member 70 is released from the latched state to the position P2 where the clamp guide release plate 100 is rotated without stopping at the latching position P1, the working optical fiber returns to the linear state. At the same time, the clamp guide 50 opens, so that the working optical fiber jumps out of the short break switching device by the upward biasing force, and the working optical fiber can be automatically taken out.

<Summary>
In the above embodiment, the latch mechanism is configured by engaging the notch 63 of the lever 60 and the groove 71 of the pressing member 70, and the latch state in which the movement of the magnet support 90 is restricted by the latch mechanism. Then, as shown in FIG. 6A, in the magnet support portion 90, the first operating mechanism side magnet 91 (first magnet) and the bending mechanism side magnet 15 face each other in a state where a force is urged from the spring 94. The bending mechanism support portion 13 is located at a position where the bending portion 11 is separated from the bending guide 21 by the magnetic force between the first operating mechanism side magnet 91 and the bending mechanism side magnet 15. Then, when the latched state by the latch mechanism is released, the magnet support portion 90 moves by the force biased by the spring 94, and the second operation mechanism side magnet 92 (second magnet), the bending mechanism side magnet 15 and the like. The bending mechanism support portion 13 moves in a direction in which the bending portion 11 approaches the bending guide 21 by the magnetic force of the second operation mechanism side magnet 92 and the bending mechanism side magnet 15. As a result, it is possible to bend the working optical fiber that is the target of short break switching instantaneously and accurately regardless of the skill of the operator.

  Further, in the above embodiment, the magnet support portion 90 has the pressing member 70 pressed by the operator, and the second operation mechanism side magnet 92 and the bending mechanism side magnet 15 as shown in FIG. When the pressing member 70 is pressed when the first support mechanism side magnet 91 and the bending mechanism side magnet 15 are in a state where the force is urged from the spring 94, the pressing member 70 is pressed. The bending mechanism support section is located at a position where the bending section 11 is separated from the bending guide 21 by the magnetic force between the first operating mechanism side magnet 91 and the bending mechanism side magnet 15. (See FIG. 7C.) The latch mechanism is in a latched state in which the movement of the magnet support portion 90 is restricted while a force is urged from the spring 94. That is, if an operation for releasing the working optical fiber 200 in the bent state to a straight state is performed, the movement of the magnet support portion 90 can be returned to the latched state (see FIG. 6A), so that Can be prepared for the switching operation.

  In the above embodiment, the latch mechanism has the lever 60 and the lever spring 65 (see FIG. 3). The lever 60 can regulate the movement of the magnet support portion 90 by engaging with the pressing member 70. By operating the lever 60, the engagement between the lever 60 and the pressing member 70 is released and the latched state is released, so that the switching operation can be executed instantaneously and accurately. Further, when the pressing member 70 is pressed and the magnet support portion 90 is in a position where the first operation mechanism side magnet 91 and the bending mechanism side magnet 15 face each other, the lever 60 is pressed by the biasing force of the lever spring 65. Since it engages with the member 70, it can naturally return to the latched state and can be prepared for the next switching operation.

  Further, in the above embodiment, when the pressing member 70 is pressed to a predetermined position in a state where the working optical fiber 200 is bent between the bending portion 11 and the bending guide 21 (see FIG. 7B). Then, the bending portion 11 is separated from the bending guide 21 and the working optical fiber 200 is released from the bending portion 11 (see FIG. 7C). When the pressing member 70 is further pressed from the predetermined position, the clamp guide 50 is opened by the clamp guide release plate 100, and the working optical fiber 200 is moved between the clamp table (82, 83) and the clamp guide 50. It is released from the state sandwiched between them (see FIG. 8). Accordingly, the bending state releasing operation by the bending portion 11 and the clamping state releasing operation by the clamp guide 50 can be performed only by operating the pressing member 70. If the clamp guide 50 is in an open state in a state where the working optical fiber 200 is bent, the working optical fiber 200 may fall off the bent portion 11, but in this embodiment, Since the clamp guide 50 is in an open state after the bending portion 11 is separated from the bending guide 21, it is possible to prevent the working optical fiber 200 from dropping from the bending portion 11 before the bending portion 11 is separated from the bending guide 21.

  In the above-described embodiment, the clamp guide release plate 100 includes the release action plate 103 (first contact portion) that contacts the magnet support portion 90 and the clamp guide pressing plate 104 (second contact) that contacts the clamp guide 50. Contact portion). When the pressing member 70 is further pressed from a position (predetermined position) where the bending portion 11 is separated from the bending guide 21, the pressing guide 70 presses the release action plate 103 to rotate the clamp guide release plate 100. Then, the clamp guide pressing plate 104 urges the clamp guide 50 in the direction in which the clamp guide 50 is opened (see FIG. 9). Thereby, the clamp guide 50 can be opened against the biasing force of the clamp guide spring 57 that biases the clamp guide 50 in the closing direction.

  Moreover, in the said embodiment, since the lever 60 and the pressing member 70 which perform operation for short break switching operation | work are arrange | positioned at the rear-end surface of a housing | casing, the several short break switching apparatus 1 is arrange | positioned in parallel, etc. Even when it is not possible to secure a large space for performing short break switching work on the left and right sides of the housing, the work can be performed easily and accurately.

=== Other Embodiments ===
The above-described embodiments are for facilitating the understanding of the present invention, and are not intended to limit the present invention. The present invention can be modified and improved without departing from the gist thereof, and it goes without saying that the present invention includes equivalents thereof. For example, the configuration of the short break switching device according to the above embodiment or the shape and structure of each part can be changed as appropriate. Also, the application is not limited to short break switching. For example, it can be used as various inspection devices such as connecting a bypass optical fiber to an optical signal detection device or a measurement device without connecting to an optical transmission line. In any case, any application that uses light leaked from an optical fiber to which bending is applied may be used.

  There may be no loss application bend and a corresponding loss application bend guide. The springs used in various mechanisms of the short break switching device according to the above embodiment, such as a clamp guide spring, are coil springs, but a predetermined member such as a torsion spring or a leaf spring is attached in a predetermined direction. Any type of spring may be used as long as it can be applied. Further, in the above-described embodiment, each member is urged using the restoring force of the coil spring in the compressed state. However, the member may be urged using the restoring force of the coil spring in the extended state.

  In the above embodiment, the latch mechanism has a structure in which the notch at the lower end of the lever is engaged with the groove formed on the side surface of the columnar pressing member. However, for example, a ring-shaped protrusion is formed on the peripheral surface of the pressing member. The structure of the latch mechanism can be designed as appropriate, for example, by engaging the notch of the lever with the protrusion.

  The magnet support portion need not be disposed below the bending mechanism side support portion. For example, the bending mechanism side support part can be disposed on the back surface of the support part or on the upper surface than the bending part. In this case, the first operating magnet and the bending mechanism side magnet may face each other with different polarities, and the second operating magnet and the bending mechanism side magnet may face each other with the same polarity.

  In the above embodiment, assuming that a plurality of units are arranged in parallel on the left and right, the operation system is arranged on both the front and rear sides, and the moving direction of the pressing member and the magnet support portion is the front and rear direction. If the work space is secured, for example, the pressing member and the magnet support portion may be configured to move in the left-right direction.

  The clamp guide release mechanism in the above-described embodiment rotates the clamp guide release plate clockwise as viewed from above by the operation of pushing the press member deeply, so that the clamp guide is pressed below the clamp guide biased to the right. Although the plate is pressed leftward and the upper part of the clamp guide is opened rightward, the clamp guide release plate may be rotated counterclockwise by an operation of pressing the pressing member deeply. In this case, for example, a region where the clamp guide pressing plate abuts from the left side may be formed in the upper region of the clamp guide. As a result, the upper region of the clamp guide that is biased to the left along with the rotation of the clamp guide release plate is biased to the right. In any case, any mechanism may be used as long as it presses the pressing member to urge the clamp guide in the open state via a predetermined link mechanism. Of course, the clamp guide releasing mechanism can be omitted.

1 short break switching device, 1i internal structure of short break switching device, 10 bending mechanism,
11 Bending part for detouring, 12 Bending part for loss application, 13 Bending mechanism support part,
15 bending mechanism side magnet, 20 bending guide mechanism, 21 detour bending guide,
22 Bending guide for applying loss, 30 housing, 32 front surface of housing, 33 rear surface of housing,
35 Slope of rear of housing, 50 Clamp guide, 51 Upper end of clamp guide,
52 Front and rear end faces of the clamp guide, 53 Clamp guide shaft hole,
54 Clamp guide bearing, 57 Clamp guide spring, 60 Lever,
62 lever shaft, 63 lever notch, 64 flat plate at the bottom of the lever,
65 spring for lever, 70 pressing member, 71 groove of pressing member, 80 base,
82 first clamp table, 83 second clamp table, 84 third clamp table,
87 Clamp guide shaft, 90 magnet support, 91 first operation mechanism side magnet, 92 second operation mechanism side magnet, 94 magnet operation spring,
100 Clamp guide release plate, 101 Clamp guide protrusion,
102 Clamp guide release mechanism shaft, 103 Release action plate,
104 Clamp guide pressing plate, 200 Working optical fiber, 210 Detour optical fiber, 220 Optical fiber probe,

Claims (5)

A switching device that inputs and outputs an optical signal between the bent portion and the detour optical fiber by bending the current optical fiber in the optical transmission line,
A bending portion and a bending guide for bending the working optical fiber; and a bending mechanism support portion to which the bending portion and a bending mechanism side magnet are fixed. The bending portion is moved by the movement of the bending mechanism support portion. A bending mechanism that moves relative to the bending guide;
A movable magnet support to which the first magnet and the second magnet are fixed;
A spring for biasing the magnet support portion;
A latch mechanism for restricting movement of the magnet support portion,
In the latch state in which the movement of the magnet support portion is restricted by the latch mechanism,
The magnet support portion is located at a position where the first magnet and the bending mechanism side magnet face each other in a state where a force is applied from the spring.
The bending mechanism support portion is located at a position where the bending portion is separated from the bending guide by the magnetic force of the first magnet and the bending mechanism side magnet,
When the latch state by the latch mechanism is released,
The magnet support portion is moved by the force urged from the spring and is in a position where the second magnet and the bending mechanism side magnet face each other.
The switching device, wherein the bending mechanism support portion moves in a direction in which the bending portion approaches the bending guide by the magnetic force of the second magnet and the bending mechanism side magnet. The switching device according to claim 1,
The magnet support part has a pressing member pressed by an operator,
When the pressing member is pressed when the second magnet and the bending mechanism side magnet are in positions facing each other,
The magnet support portion is in a position where the first magnet and the bending mechanism side magnet face each other in a state where a force is applied from the spring.
The bending mechanism support portion is located at a position where the bending portion is separated from the bending guide by the magnetic force of the first magnet and the bending mechanism side magnet,
The switching device according to claim 1, wherein the latch mechanism is in the latch state in which movement of the magnet support portion is restricted in a state where a force is urged from the spring. The switching device according to claim 2,
The latch mechanism has a lever and a lever spring,
The lever can regulate the movement of the magnet support portion by engaging with the pressing member,
By operating the lever, the lever and the pressing member are disengaged to release the latched state.
When the pressing member is pressed and the magnet support portion is in a position where the first magnet and the bending mechanism side magnet face each other, the lever is engaged with the pressing member by the biasing force of the lever spring. A switching device characterized by combining. The switching device according to claim 2 or 3,
A clamp base and a clamp guide for sandwiching the working optical fiber;
A clamp guide releasing mechanism that opens the clamp guide in conjunction with the pressing member being pressed;
With
The clamp guide sandwiches the working optical fiber between the clamp base and the clamp base by the urging force of the clamp guide spring,
When the pressing member is pressed from a predetermined position where the bending portion and the bending guide are separated from each other, the clamp guide is opened by the clamp guide release mechanism, and the working optical fiber is connected to the clamp base and the clamp base. A switching device that is released from a state of being clamped with a clamp guide. The switching device according to claim 4,
The clamp guide release mechanism has a first contact portion that contacts the magnet support portion and a second contact portion that contacts the clamp guide,
When the pressing member is pressed from the predetermined position, the clamp support releasing mechanism is rotated by the magnet support portion pressing the first contact portion, and the second contact portion is rotated by the clamp guide. A switching device characterized by energizing in a direction to open the switch.