JP2008083622A - Optical connecting member and coated optical fiber collation method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an optical connecting member that makes collation of coated optical fibers possible during optical communication without taking off the connection of the optical connecting member and that also facilitates the collation without giving physical bend or deformation to the coated optical fibers, and to provide a coated optical fiber collation method using this optical connecting member. <P>SOLUTION: The optical connecting member 20 is disclosed which attachably and detachably connects between coated optical fibers for optical signal transmission and which is equipped with an optical derivation mechanism for leading out visible light inputted in the coated optical fibers, to the outside in an optically connected state. As the optical derivation mechanism, for example, a filter member 27 for reflecting visible light is arranged in a ferrule 22 in which an optical fiber 21 is inserted, to emit the visible light to the outside. Alternatively, the ferrule member with the optical fiber 21 inserted may be made of crystallized glass, diffusively transmitting leakage of the visible light on and around the connecting end face of the optical fiber, and thereby emitting the visible light to the outside. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an optical connection member used for interconnection of optical fiber core wires in an optical wiring board or the like, and a core wire contrast method for performing contrast of core wires using the optical connection member.

  An optical transmission system is a system that lays an optical cable composed of an optical fiber core wire between a station and another station or between a station and a subscriber terminal to transmit and communicate with each other. Many optical fiber cores are optically connected to other stations and subscribers' homes using optical connection members etc. on the optical distribution board in the station. When newly laying or changing connections, the optical fiber cores are specified. A heart contrast is performed. For example, as disclosed in Patent Document 1, an optical coupler is provided for each of the optical fiber cores connected to the optical wiring board, and the optical coupler is selected by selecting the optical coupler. A method is disclosed in which a core wire is contrasted by allowing visible light (or control light) to enter the optical fiber and diffusing and transmitting visible light through an optical connector cap provided at a terminal on the terminal side of the optical fiber core wire. Yes.

Patent Document 2 discloses an IR filter that converts control light (not visible light) that has entered the optical fiber cord into a cover of a connection adapter from which one of the optical connectors is removed, and converts the control light into visible light. There is disclosed a method in which such an optical element is incorporated, and when contrast light hits the optical element, it is converted to visible light and visually contrasted. Patent Document 2 also discloses a method for detecting control light that is bent at an inflection point by bending an optical fiber cord when the optical connector is not detached.
JP 2000-88704 A Japanese Patent No. 3363383

  According to the above-described conventional technology, the control light is directly incident on the optical fiber core via the optical coupler, and the control light is diffused and transmitted through the optical connector cap on the terminal side, so that the optical fiber core can be easily visually checked. It is supposed to be possible. However, many optical fiber core wires (or optical fiber cords) and optical connectors are densely congested in a highly dense optical wiring facility in a station or the like. For this reason, when detecting a failure such as a change in wiring or disconnection using a jumper wire, an identification means such as a bar code is attached to the optical fiber core wire. Since the surroundings of the device are dark, the above-mentioned core line contrast operation is difficult. As a result, it takes time to identify the port that is the subject of the control of the core, and other optical connectors that are communicating may be erroneously inserted or removed.

  In addition, the above-described core wire contrast in Patent Documents 1 and 2 is performed for a non-communication optical fiber core wire that does not have signal light. Such work is required. The above-mentioned Patent Document 2 also shows an example in which the optical fiber cores are compared without removing the optical connector. However, the optical fiber cores are bent to cause leakage light. Therefore, there is a problem that the optical fiber core wire during other communication is also bent, causing a loss variation with respect to the steady optical communication and causing a communication abnormality.

  The present invention has been made in view of the above-described circumstances, and enables the optical fiber cores to be compared in the optical communication state without disconnecting the optical connecting member, and the optical fiber cores are physically bent. An object of the present invention is to provide an optical connecting member capable of easily performing a core wire contrast without giving any distortion, and a core wire contrast method using the optical connecting member.

  An optical connection member according to the present invention is an optical connection member that detachably connects optical fiber cores used for optical signal transmission, and visible light input into the optical fiber core is externally connected in an optical connection state. A light derivation mechanism for derivation is provided. As this light derivation mechanism, for example, a filter member that reflects visible light is disposed in a ferrule through which an optical fiber is inserted, and the visible light is emitted to the outside. Further, the ferrule member into which the optical fiber is inserted may be formed of crystallized glass, and the visible light leakage light may be diffused and transmitted at the optical fiber joint end face and the vicinity thereof to emit the visible light to the outside. . Note that red laser light can be used as the visible light. Moreover, the function of the said light derivation | leading-out mechanism can be provided in either the optical connector with which the optical fiber core wire was mounted | worn, or the connection adapter which connects optical connectors.

  According to the present invention, without disconnecting an optical connecting member such as an optical connector, the optical fiber cores can be compared while maintaining the connected state, and workability without causing erroneous insertion and removal of the optical connector is achieved. Can be improved. Furthermore, since the optical fiber core wire is not physically bent or distorted, it is possible to perform the core wire contrast during the optical communication without affecting the optical communication.

  Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a diagram for explaining an example of a core line control system according to the present invention, in which a part of the system disclosed in Patent Document 1 is used. In the figure, 1 is an optical transmission device, 2 is a star coupler rack, 3 is an optical cable termination rack, 4 (4a to 4d) is an optical cable (fiber optic cable), 5 (5a to 5d) is a subscriber terminal, 6 ( 6a to 6d) are optical fibers (branching optical fibers), 7a to 7d are jumper wires, 8 and 9 are optical connecting members (optical connectors), 10a and 10 are optical wiring boards, and 11 (11a to 11d) are optical branching modules. (Optical couplers) 12, 13 are branch optical fibers, 14 is an optical switch, 15 is a control device, 16 is a visible light source, 17 is an optical pulse tester, and 18 is a loss test light source.

  The optical transmission device 1 sends out signal light to be transmitted to each of the subscriber terminals 5 to the star coupler rack 2 via the optical fiber 6. In the star coupler rack 2, in order to distribute signal light from the optical transmission device 1 to a large number of subscriber terminals, the optical fiber 6 is multi-branched into branch optical fibers 6a to 6d by the star coupler 2a (in the example of four branches in the figure). And signal light is transmitted to each of them. The output ends of the branched optical fibers 6a to 6d are connected to the optical connection member 8 disposed at a high density on the optical wiring board 10a. In order to simplify the description, the number of optical fibers is four, but in actuality, the optical fibers are composed of several tens to several hundreds.

  The signal light from the star coupler rack 2 is sent to the optical fiber core wire of the optical cable termination rack 3 through the jumper wires 7a to 7d. The optical cable termination 3 includes an optical wiring board 10b, an optical branching module 11, and an optical switch 14. In the optical wiring board 10b, a large number of optical connection members 9 for receiving the signal light from the optical transmission device 1 through the jumper wires 7a to 7d are arranged with high density. Connected to the optical connecting member 9 are input ends of optical fiber cores 4a to 4d for transmitting the received signal light to the subscriber terminal 5 side. The optical branching module 11 has a large number of optical couplers 11 a to 11 d and is provided on the respective paths of the optical fiber core wires 4 a to 4 d of the optical cable 4. Each of the optical couplers 11 a to 11 d has, for example, two branch optical fibers 12 and 13, and the connection is selected by the optical switch 14.

  For example, when light is sent from the optical fiber 11a to the branch optical fiber 12 of the optical coupler 11a, visible light is transmitted toward the subscriber terminal 5a via the optical fiber 4a. The On the other hand, when light is sent from the visible light source 16 to the branch optical fiber 13, visible light is transmitted toward the optical connection member 9 via the optical fiber core 4a. The selection of the branch optical fibers 12 and 13 is performed by the optical switch 10 controlled by the control device 15. The optical switch 14 is also used for selecting the optical pulse tester 17 for transmitting the pulsed light and the loss test light source 18 for testing the transmission loss, in addition to selecting the transmission of visible light for contrast control. Used.

  As the visible light source 16, a light source that emits visible light (400 nm to 750 nm) can be used. Since red light is relatively easy to identify with respect to the optical connecting member, it is desirable to use red laser light of 600 nm or more from a red laser light source. Further, since visible light passing through the optical fiber has a transmission loss larger than the wavelength band (1.31 μm, 1.55 μm) used for signal light for information transmission, the optical switchboard in the station (for example, several tens to several hundreds) It is suitable for use as a cord contrast by the optical connecting members 8 and 9 installed at a distance of m).

  In addition, in the construction work of the optical cable for the subscriber terminal, etc., it can be dealt with by bringing the test device to the vicinity of the construction site. Further, when the distance between the cores becomes longer, it is possible to cope with the problem by using a visible light source having a high optical power. The optical pulse tester 17 sends pulsed light to the optical fiber cores 4a to 4d, detects backscattered light accompanying this, and performs an ODTR test. Further, as the loss test light source 16, for example, a 1.65 μm band light source is used, and a loss test of the optical transmission path to the subscriber terminal 5 is performed.

  In the above-described core wire contrast system, the core wire contrast can be performed at the subscriber terminal, but the optical wiring board 10a, in which a large number of optical fiber core wires and a large number of optical connection members 8 and 9 are arranged. Often performed at 10b. In contrast, for example, the optical fiber core 4a to be compared with the optical switch 14 and the branch optical fiber 13 are selected to transmit light (for example, red laser light) transmitted from the visible light source 16. Suppose that In this case, the visible light is transmitted to the optical fiber 13 of the optical coupler 11a, is incident on the optical fiber core 4a from the optical coupler 11a, and is transmitted toward the optical connecting member 9 provided at the input end. .

  Here, in the conventional case, the optical connector on the side of the optical fiber core 4a left on the optical wiring board is removed from the optical wiring board 10b by removing the optical connector on the side of the jumper wire 7a for sending the signal light of the optical connecting member 9. Put the cap on the connector. Then, it is visually confirmed that the visible light from the visible light source is diffused and transmitted to the cap, and the cord is contrasted. However, since both of the optical fiber core wires and the optical connectors are congested on both sides of the optical wiring board 10b, it is difficult to identify the core wires and to remove one of the optical connectors. If this optical connector is mistakenly removed, communication may be interrupted in the line during communication, which may cause a major failure.

  In the present invention, it is the same as the conventional practice to perform the core line contrast at the optical connection member 8 or 9, but the core line contrast can be performed in the communication state without removing the optical connection member. Yes. Specifically, the optical connecting members 8 and 9 are provided with a light deriving mechanism for deriving the visible light transmitted into the optical fiber core wire, and the visible light emitted from the light deriving mechanism is visually observed. , I'm trying to contrast the cores.

2 to 5 are views for explaining an optical connecting member according to the present invention, FIG. 2 is a view for explaining an example in which a light derivation mechanism is provided in the optical connector, and FIG. 3 is a view for explaining the configuration of a ferrule of the optical connector. FIG. 4 is a diagram for explaining an example in which a light derivation mechanism is provided in a connection adapter, and FIG. 5 is a diagram for explaining another embodiment.
2 and 3, 20 is an optical connector, 21 is an optical fiber core wire, 22 is a ferrule, 23 is a ferrule holder, 24 is a connector housing, 25 is a spring, 26 is a window, 27 is a reflection filter, and 28 is a reflection filter. A boot 29 indicates a slit.

  As shown in FIG. 2A, the optical connector 20 has the same shape as a general optical connector structure. For example, the coating of the optical fiber core wire 21 is removed from the ferrule 22 and the end portion of the glass fiber. To insert and integrate. The ferrule 22 is held by a ferrule presser 23 and is mounted on the connector housing 24 while being urged in the axial direction by a spring 25 or the like. The lead-out portion of the optical fiber core wire 21 is protected by a boot 28 made of a resilient material such as rubber. Further, as shown in FIG. 2B, the optical connector has an external shape in which a latch lever 24a for operating insertion / extraction of the optical connector 20 is integrally provided in the connector housing 24, and the ferrule 22 extends from the tip of the connector housing 24. Is configured to protrude slightly.

  In the optical connecting member (optical connector) of the present invention, a reflection filter 27 is inserted into a ferrule so that visible light transmitted into an optical fiber is led to the outside. A window portion 26 capable of transmitting visible light is formed. By configuring the optical connector 20 in this way, the visible light transmitted toward the optical connector 20 in the optical fiber core wire 21 is reflected outside the optical fiber by the reflection filter 27, and the window portion 26. The light can be emitted to the outside through the optical connector.

  As shown in FIG. 2 (B), visible light emitted through the window portion 26 can be easily visually confirmed from the outside by causing the exit portion of the window portion 26 provided on the side surface of the connector housing 24 to shine. Can do. As a result, it can be detected that visible light is being sent to the optical fiber core wire 21. Therefore, by using the optical connector 20 of FIG. 2 for the optical connectors of the optical connecting members 8 and 9 of FIG. 1, it is possible to perform the contrast control without removing one of the optical connectors.

  A dielectric multilayer filter is used for the reflection filter 27. This dielectric multilayer filter is configured so that, for example, light having a wavelength of λ1 or less can be transmitted, but light exceeding the wavelength λ2 can be reflected or absorbed. The wavelengths of λ1 and λ2 are It can be set according to the thickness of the filter and the laminated structure. Various dielectric multilayer filters are known, but can be appropriately selected and used depending on the wavelength (color) of visible light to be used.

  As shown in FIGS. 3A and 3B, the reflection filter 27 can be inserted into a slot 29 formed in the ferrule 22 and incorporated. The slot 29 is formed by inserting the glass fiber 21a from which the optical fiber coating is removed into the fiber hole of the ferrule 22 and bonding and integrating it. Then, the slot 29 is cut at a predetermined angle θ so as to cross the ferrule shaft. It is formed so as to divide 21a. The angle θ of the slot 29 is 2 ° or more, preferably 4 ° to 8 °. This angle is formed at an angle that prevents visible light that has traveled straight through the optical fiber from returning into the optical fiber.

  As the dielectric multilayer filter used for the reflection filter 27, for example, it is desirable to use a polyimide filter based on polyimide that is inexpensive and easy to handle and can be used in a wide range of wavelengths. FIG. 3C shows an example of the transmission loss of the red cut filter in the case where red laser light is used as visible light for contrasting the core. As shown in FIG. 3C, this filter characteristic has a large transmission loss in the red wavelength region (650 nm to 750 nm), and a transmission loss of 50 dB or more at a wavelength of 650 nm. Further, for the wavelengths of 1310 ± 20 nm, 1550 ± 20 nm and test light 1650 ± 20 nm used for normal signal light, the insertion loss due to filter insertion is 0.5 dB or less, and the return loss is 37 dB or more. It is.

  By inserting such a reflection filter into the ferrule portion of the optical connector, visible light can be reflected and emitted out of the optical fiber, and part of the visible light can be absorbed so as not to pass through the reflection filter. On the other hand, the signal light passing through the optical fiber together with the visible light has little insertion loss due to the reflection filter, and does not substantially affect the communication of the signal light. Therefore, even if visible light for controlling the optical fiber is sent to the optical fiber that is communicating with the optical connector connected, the communication can be continued without any trouble in optical communication. it can. Then, the visible light transmitted into the optical fiber is led out from the side surface of the optical connector, emitted, and confirmed by visual observation to perform the contrast control.

  FIG. 4 is a diagram showing an optical connection member for connecting optical connectors to each other via a connection adapter, in which 30 is a connection adapter, 31 is a glass fiber, 32 is an adapter ferrule, 33 is a holding sleeve, and 34 is an adapter housing. , 35a and 35b are receptacle parts, and 36 is an adapter window part. Description of other reference numerals is omitted by using the same reference numerals as those used in FIG.

  In the example of FIG. 4, the light derivation mechanism formed in the optical connector 20 described in FIG. 2 is provided on the connection adapter 3 side. The connection adapter 30 has receptacles 35 a and 35 b into which optical connectors are inserted at both ends, and an adapter ferrule 32 is held by a holding sleeve 33 at the center. The adapter ferrule 32 has a glass fiber 31 inside, and a reflective filter 37 is inserted into the adapter ferrule 32 in order to emit visible light transmitted into the optical fiber to the outside. This configuration can be said to be close to a fixed attenuator in shape. The adapter housing 34 is formed with a window 36 capable of transmitting light in the vicinity of the reflection filter 37. Since the connection adapter 30 is usually provided with a flange for attachment to a support panel or the like at the center of the adapter housing 34, the window hole 36 is formed on a side surface that does not have this flange.

  The reflection filter 37 is incorporated in the adapter ferrule 32 in the same manner as described for the ferrule for optical connectors in FIG. Also, the same dielectric multilayer filter used as the reflection filter 37 can be used as used for the ferrule of the optical connector. The optical connector 20 is inserted into the receptacle portions 35a and 35b of the connection adapter 30, and the end faces of the ferrule 22 and the adapter ferrule 32 of the optical connector 20 are abutted to form an optical connection. In this case, the optical connector 20 can be a normal optical connector that does not have a light derivation mechanism.

  By configuring the connection adapter of the optical connection member as described above, visible light transmitted from the optical fiber core wire 21 into the optical connector 20 is reflected by the reflection filter plate 37 incorporated in the adapter ferrule 32. The light can be emitted to the outside through the window 36 of the adapter housing. Visible light emitted through the window portion 36 is emitted from the window portion 36 provided on the side surface of the adapter housing 24 and can be easily confirmed visually from the outside. As a result, it can be detected that visible light is being sent to the optical fiber core wire 21. Therefore, by using the connection adapter 30 of FIG. 3 as the optical connection members of the optical connection members 8 and 9 of FIG. 1, it is possible to perform the core line contrast without removing the optical connector.

  FIG. 5 is an example of an optical connection member using a connection adapter as in FIG. 4, and is a diagram illustrating another embodiment that does not use a reflection filter. In the figure, 40 is an optical connector, 42 is a ferrule, 43 is a ferrule holder, 44 is a connector housing, 45 is a spring, 46 is a window, 47 is a butt end face, 50 is a connection adapter, 51 is an adapter housing, 52a, 52b shows a receptacle part. Description of other reference numerals is omitted by using the same reference numerals as those used in FIG.

  The optical connection member of FIG. 5 optically connects the optical fibers 21 by inserting the optical connector 40 into the receptacles 52a and 52b of the connection adapter 50. The shape of the optical connector 40 is the same as that described with reference to FIG. 2. For example, the optical fiber 21 is removed from the ferrule 42 and the end portion of the glass fiber is inserted and integrated. The ferrule 42 is held by a ferrule retainer 43 and is mounted on the connector housing 44 while being biased in the axial direction by a spring 45 or the like.

In addition, although not shown in the figure, as in the optical connector of FIG. 2, the lead-out portion of the optical fiber core wire 21 is protected by a boot made of a resilient material such as rubber. Further, a latch lever or the like for operating the insertion / extraction of the optical connector 20 is integrally provided in the connector housing 24, and the ferrule 22 is configured to protrude slightly from the tip of the connector housing 24.
The connection adapter 50 includes a housing housing 51 formed to position the pair of optical connectors 40, abut the ferrule end faces, and hold the connection.

  In the optical connecting member shown in FIG. 5, the ferrule 42 of the optical connector is formed of crystallized glass that diffuses and transmits visible light (red laser light), and the connector housing 44 has visible light as in FIG. A feature is that a window portion 46 capable of transmitting light is provided. The optical connectors 40 are butt-connected using the connection adapter 50, and the core axis of the optical fiber at the butt end face 47 is often slightly shifted. For this reason, visible light passing through the core leaks from the butt end face 47 of the ferrule 42 and diffuses into the ferrule 42 to emit light. In addition, when using a ferrule made of crystallized glass, the visible light sent into the optical fiber diffuses and transmits the leaked light from the side surface of the glass fiber into the ferrule 42, as shown by the dotted line in the figure, The ferrule 42 emits light by visible light around the butting surface 47. Also in this example, similarly to FIG. 4, a window portion that emits visible light to the outside may be provided on the connection adapter 50 side, and light may be emitted from the connection adapter.

  The visible light diffused into the ferrule 42 as described above is emitted to the outside from the window portion 46 of the connector housing 44. Visible light emitted through the window 46 can be easily visually confirmed from the outside as described with reference to FIG. As a result, it can be detected that visible light is being sent to the optical fiber core wire 21. Therefore, by using the optical connection member (optical connector 30) of FIG. 5 for the optical connectors of the optical connection members 8 and 9 of FIG. 1, it is possible to perform the contrast control without disconnecting the optical connector.

  However, in the optical connecting member of FIG. 5, even if the visible light transmitted into the optical fiber core wire is attenuated by the optical connector 40, the remaining visible light is transmitted to the optical transmission device side. For this reason, it is necessary to arrange the reflection filter used in the optical connector of FIG. 3 at the outlet of the optical transmission device to prevent the visible light from being input to the optical transmission device.

  Further, in the optical fiber reference system of FIG. 1, when the optical connection member having the configuration using the reflection filter of FIGS. 2 to 4 is used as the optical connection member 9 of the optical wiring board 10 b, it is visible at the optical connection member 9. The light is cut. Therefore, visible light is not sent to the optical connecting member 8 on the optical wiring board 10a side, and the core line contrast on the optical wiring board 10a side cannot be performed. Therefore, the optical connection member of the embodiment shown in FIG. 5 is used for the optical connection member 9 on the optical wiring board 10b side, and the optical connection member 8 of the embodiment shown in FIGS. A connecting member is used. As a result, it is possible to perform the contrast control without removing the optical connector on the optical wiring board 10b side, and it is possible to perform the contrast control without removing the optical connector on the optical wiring board 10a side. Further, since visible light can be blocked by the optical connector on the optical wiring board 10a side, it is not necessary to provide a reflection filter for preventing the input of visible light in the optical transmission device.

As described above, an example in which visible light is transmitted from the transmission apparatus side has been described as an embodiment of the present invention. However, in the construction work of an optical cable or the like, visible light is transmitted from the subscriber terminal side, and the optical cable termination is performed from the subscriber terminal. The present invention is also effective when performing contrast control between the two.
Further, in the embodiment of the present invention, an example in which a window portion is provided in the connector housing and visible light is visually recognized from the outside of the connector has been shown, but a connector housing formed of a transparent material is used instead of the window portion. Thus, the same effect can be obtained.
Furthermore, in the embodiment of the present invention, an example in which the visible light derived from the optical connector is visually confirmed has been shown. However, when the visible light intensity is low and it is difficult to visually recognize, it is possible to use an optical sensor together. is there.

It is a figure explaining an example of the core line contrast system concerning the present invention. It is a figure which shows the example which provides the optical derivation | leading-out mechanism in an optical connector with the optical connection member by this invention. It is a figure explaining the structure of a ferrule in the optical connection member by this invention. It is a figure which shows the example which provides an optical derivation | leading-out mechanism in a connection adapter with the optical connection member by this invention. It is a figure explaining other embodiment of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Optical transmission apparatus, 2 ... Star coupler frame, 3 ... Optical cable termination frame, 4 (4a-4d) ... Optical cable (optical fiber core wire), 5 (5a-5d) ... Subscriber terminal, 6 (6a-6d) ) ... Optical fiber (branching optical fiber), 7a-7d ... Jumper wire, 8, 9 ... Optical connecting member (optical connector), 10a, 10 ... Optical wiring board, 11 (11a-11d) ... Optical branching module (optical coupler) , 12, 13 ... Branch optical fiber, 14 ... Optical switch, 15 ... Control device, 16 ... Visible light source, 17 ... Optical pulse tester, 18 ... Light source for loss test, 20, 40 ... Optical connector, 21 ... Light Fiber core, 22, 42 ... Ferrule, 23, 43 ... Ferrule holder, 24, 44 ... Connector housing, 25, 45 ... Spring, 26, 46 ... Window, 27 ... Reflection filter, 28 ... Boot, 29 ... Slit , 0, 50 ... Connection adapter, 31 ... Glass fiber, 32 ... Adapter ferrule, 33 ... Holding sleeve, 34, 51 ... Adapter housing, 35a, 35, 52a, 52b ... Receptacle part, 36 ... Adapter window part, 47 ... Light Butt end face.

Claims (7)

  An optical connecting member for detachably connecting optical fiber cores used for optical signal transmission, comprising a light derivation mechanism for guiding visible light input into the optical fiber cores to the outside in an optical connection state An optical connection member.   The light derivation mechanism is configured to dispose the visible light to the outside by disposing a filter member that reflects the visible light and transmits the signal light in a ferrule through which an optical fiber is inserted. The optical connection member according to claim 1.   The light derivation mechanism is configured such that a ferrule into which an optical fiber is inserted is formed of crystallized glass, and the visible light leakage light is diffused and transmitted at and near the optical fiber joint end surface to emit the visible light to the outside. The optical connection member according to claim 1.   The optical connection member according to claim 1, wherein red laser light is used for the visible light.   The optical connection member according to claim 1, wherein the light guide mechanism is provided on an optical connector side to which an optical fiber core wire is attached.   The optical connection member according to any one of claims 1 to 4, wherein the optical derivation mechanism is provided on an optical connection adapter side for connecting optical connectors to each other.   Using the optical connecting member according to any one of claims 1 to 6, the visible light input into the optical fiber core wire is emitted to the side of the optical connecting member to perform the core wire contrast. Contrast method.

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