JP6492972B2 - Communication light visualization code - Google Patents

Description

  The present invention relates to a communication light visualization code for realizing visualization of communication light transmitted through an optical communication path for the purpose of visual confirmation of a communication state in the optical communication path.

  An optical communication-related facility may be equipped with a communication light visualization structure for realizing visualization of communication light transmitted through the optical communication path for the purpose of visually confirming the communication status in the optical communication path. As a communication light visualization structure, a part of communication light transmitted through the optical communication path is made leak light by interposing a light scattering medium in the optical communication path, and optical communication is performed by detecting the leak light with a light receiving element. It is possible to visually check the communication status in the optical communication path by determining whether the communication light is transmitted through the path and displaying to the worker through the light emitting element whether the communication light is transmitted through the optical communication path. (For example, see Patent Documents 1 to 4).

JP 2009-145676 A JP 2010-231082 A JP 2011-013359 A JP 2011-013360 A

  In optical communication-related equipment equipped with a communication light visualization structure, the communication status in the optical communication path can be visually confirmed, so monitoring and maintenance of the optical communication path can be performed easily. Since the structure is a new technology, there are also optical communication-related facilities that do not implement the communication light visualization structure. When the communication light visualization structure is installed in these optical communication-related facilities, it may be necessary to replace the patch panel. However, replacing the patch panel requires significant system changes and multiple port communication to be stopped simultaneously. There are challenges.

  Therefore, an object of the present invention is to easily implement a communication light visualization structure in an optical communication-related facility that does not implement a communication light visualization structure without causing significant system change or simultaneous communication of a plurality of ports. It is to provide a communication light visualization code that is possible.

  The present invention is for realizing visualization of communication light transmitted through the optical communication path for the purpose of visual confirmation of the communication status in the optical communication path formed by optically connecting the first optical fiber and the second optical fiber. A communication light visualization code, which is attached to a first optical cord in which the first optical fiber is accommodated, a second optical cord in which the second optical fiber is accommodated, and a tip portion of the first optical cord The first boot, the second boot attached to the tip of the second optical cord, the first crimping ring attached to the tip of the first boot, and the second boot A second crimping ring attached to the tip, a first stopper attached to the tip of the first crimping ring, and a second stopper attached to the tip of the second crimping ring And the first A first ferrule that is held by the top and contains the tip of the first optical fiber; and a first ferrule that is held by the second stopper and contains the tip of the second optical fiber. Two ferrules, a split sleeve holding the first ferrule and the second ferrule, and being attached between the first stopper and the second stopper, and the first ferrule and the second ferrule And a ferrule cover accommodated together with the split sleeve, and the first optical fiber and the second optical fiber transmit a part of the communication light transmitted through the optical communication path as leakage light. It is the communication light visualization code | symbol optically connected via the light extraction part taken out as.

  The first optical cord contains a first tensile body together with the first optical fiber, the second optical cord contains a second tensile body together with the second optical fiber, and the first tensile strength. The tip of the body is sandwiched between the first crimping ring and the first stopper, and the tip of the second strength member is between the second crimping ring and the second stopper. It is desirable to be sandwiched between.

  According to the present invention, it is possible to easily implement the communication light visualization structure in an optical communication-related facility that does not implement the communication light visualization structure without accompanying significant system change or simultaneous communication of a plurality of ports. A communication light visualization code can be provided.

It is sectional drawing which shows the communication light visualization code | cord | chord which concerns on embodiment of this invention. It is sectional drawing which shows the 1st optical code of the communication light visualization code of FIG. It is sectional drawing which shows the 1st boot of the communication light visualization code | cord | chord of FIG. It is sectional drawing which shows the 1st crimping ring of the communication light visualization code | cord | chord of FIG. It is sectional drawing which shows the 1st stopper of the communication light visualization code | cord | chord of FIG. It is sectional drawing which shows the 1st ferrule of the communication light visualization code | cord | chord of FIG. It is sectional drawing which shows the split sleeve of the communication light visualization code | cord | chord of FIG. It is sectional drawing which shows the ferrule cover of the communication light visualization code | cord | chord of FIG.

  Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

  As shown in FIG. 1, the communication light visualization code 100 according to the embodiment of the present invention performs visual confirmation of a communication state in an optical communication path 103 formed by optically connecting a first optical fiber 101 and a second optical fiber 102. The purpose is to realize visualization of communication light transmitted through the optical communication path 103. Examples of the communication status in the optical communication path 103 include a use / non-use state of the optical communication path 103.

  The communication light visualization code 100 includes a first light cord 104, a second light cord 105, a first boot 106, a second boot 107, a first crimping ring 108, a second crimping ring 109, One stopper 110, a second stopper 111, a first ferrule 112, a second ferrule 113, a split sleeve 114, and a ferrule cover 115 are provided.

  As shown in FIG. 2, the first optical cord 104 is formed by molding a highly flexible polyvinyl chloride resin or the like into a hollow cylindrical shape, and houses the first tensile body 116 together with the first optical fiber 101. As a result, the first optical fiber 101 and the first strength member 116 can be protected. The first optical fiber 101 also has an optical fiber strand 117 composed of a core and a clad, and a protective layer 118 coated around the optical fiber strand 117, and a protective layer at the tip portion. 118 is peeled off, and the optical fiber 117 is exposed.

  In the present specification, the center end of the communication light visualization cord 100 that optically connects the first optical fiber 101 and the second optical fiber 102 is referred to as a tip portion, and ends of both ends of the communication light visualization cord 100. The part is referred to as a rear end part.

  Similarly, the second optical cord 105 is formed by molding a highly flexible polyvinyl chloride resin or the like into a hollow cylindrical shape, and houses the second strength member 119 together with the second optical fiber 102. As a result, the second optical fiber 102 and the second strength member 119 can be protected. Further, the second optical fiber 102 has an optical fiber strand 117 composed of a core and a clad, and a protective layer 118 coated around the optical fiber strand 117, and a protective layer at the tip portion. 118 is peeled off, and the optical fiber 117 is exposed.

  As shown in FIG. 3, the first boot 106 is formed by molding a highly flexible polyester elastomer or the like into a hollow cylindrical shape, and is attached to the distal end portion of the first optical cord 104. More specifically, the inner diameter of the first boot 106 gradually changes in accordance with the outer diameter difference between the first optical cord 104 and the first caulking ring 108, and the front end portion of the first boot 106 is the first boot 106. The rear end portion of the first caulking ring 108 is covered, and the rear end portion of the first boot 106 covers the front end portion of the first optical cord 104. Further, the first boot 106 has a lightening portion 120 formed by partially thinning the first boot 106. As a result, the first boot 106 can be given flexibility such that it can be deformed following the bending of the communication light visualization cord 100, and stress is easily concentrated with the bending of the communication light visualization cord 100. Since the tip portion of the one optical cord 104 can be protected, the fatigue fracture of the first optical cord 104 can be suppressed. Furthermore, the first boot 106 has a claw portion 121 having a tip portion protruding inward. The claw portion 121 has a chamfered portion 122 on the front end side and a corner portion 123 on the rear end side. As a result, the first boot 106 and the first caulking ring 108 can be easily engaged and the first boot 106 and the first caulking ring 108 can be prevented from being separated. It becomes possible to protect the tip portion of the one optical cord 104 more reliably. The first boot 106 has a stepped portion 124 formed by forming a step on the inner peripheral surface. Thereby, it is possible to suppress the first caulking ring 108 from being excessively inserted into the first boot 106.

  Similarly, the second boot 107 is formed by molding a highly flexible polyester elastomer or the like into a hollow cylindrical shape, and is attached to the distal end portion of the second optical cord 105. More specifically, the inner diameter of the second boot 107 gradually changes in accordance with the outer diameter difference between the second optical cord 105 and the second caulking ring 109, and the tip of the second boot 107 is the first boot portion. The rear end portion of the second caulking ring 109 is covered, and the rear end portion of the second boot 107 covers the front end portion of the second optical cord 105. Further, the second boot 107 has a lightening portion 120 formed by partially thinning the second boot 107. As a result, the second boot 107 can be provided with a degree of flexibility that allows the second boot 107 to be deformed following the bending of the communication light visualization cord 100, and stress is easily concentrated with the bending of the communication light visualization cord 100. Since the front end portion of the two-light cord 105 can be protected, fatigue fracture of the second optical cord 105 can be suppressed. Further, the second boot 107 has a claw portion 121 having a tip portion protruding inward. The claw portion 121 has a chamfered portion 122 on the front end side and a corner portion 123 on the rear end side. As a result, the second boot 107 and the second caulking ring 109 can be easily engaged and the second boot 107 and the second caulking ring 109 can be prevented from being separated. It becomes possible to protect the front-end | tip part of the two-light cord 105 more reliably. The second boot 107 has a step portion 124 formed by forming a step on the inner peripheral surface. Thereby, it is possible to suppress the second caulking ring 109 from being excessively inserted into the second boot 107.

  As shown in FIG. 4, the first caulking ring 108 is formed of a highly workable aluminum or the like into a hollow cylindrical shape, and is attached to the tip of the first boot 106. As a result, the first caulking ring 108 can be easily caulked to the first stopper 110. The first caulking ring 108 has a groove portion 125 formed by forming a groove on the outer peripheral surface. Accordingly, the first boot 106 and the first caulking ring 108 can be firmly fixed by engaging the claw portion 121 of the first boot 106 with the groove 125 of the first caulking ring 108. The first caulking ring 108 has a stepped portion 126 formed by forming a step on the inner peripheral surface. Thereby, it is possible to suppress the first stopper 110 from being excessively inserted into the first caulking ring 108. Further, the first caulking ring 108 has a chamfered portion 127 on the inner peripheral surface of the front end and the rear end. As a result, the first stopper 110 can be easily inserted into the first caulking ring 108, and damage to the first strength member 116 of the first cord 104 can be prevented.

  Similarly, the second caulking ring 109 is formed of a highly workable aluminum or the like into a hollow cylindrical shape, and is attached to the tip of the second boot 107. As a result, the second caulking ring 109 can be easily caulked to the second stopper 111. The second caulking ring 109 has a groove portion 125 formed by forming a groove on the outer peripheral surface. Thereby, the second boot 107 and the second caulking ring 109 can be firmly fixed by engaging the claw portion 121 of the second boot 107 with the groove 125 of the second caulking ring 109. The second caulking ring 109 has a stepped portion 126 formed by forming a step on the inner peripheral surface. Thereby, it is possible to suppress the second stopper 111 from being excessively inserted into the second crimping ring 109. Further, the second caulking ring 109 has a chamfered portion 127 on the inner peripheral surface of the front end and the rear end. As a result, the second stopper 111 can be easily inserted into the second crimping ring 109, and damage to the second strength member 119 of the second cord 105 can be prevented.

  As shown in FIG. 5, the first stopper 110 is made of brass, stainless steel or the like having a high hardness in a hollow cylindrical shape, and is attached to the distal end portion of the first caulking ring 108. Thereby, since it becomes difficult to deform | transform the 1st stopper 110, it becomes possible to fix the 1st stopper 110 and the 2nd stopper 111 firmly via the ferrule cover 115. FIG. That is, the first stopper 110 and the second stopper 111 are difficult to separate from each other without relying on the first strength member 116 or the second strength member 119. The first stopper 110 has a groove portion 128 formed by forming a groove on the outer peripheral surface. Accordingly, the first strength member 116 can be securely sandwiched between the first caulking ring 108 and the first stopper 110, so that even if the communication light visualization cord 100 is pulled, the first boot 106 and the first Since it becomes difficult to separate the crimping ring 108, the tensile characteristics of the communication light visualization cord 100 can be improved. The first tensile body 116 is formed by twisting Kepler fibers or the like having high tensile strength into a thread shape. Further, the first stopper 110 has a stepped portion 129 formed with a step on the inner peripheral surface, and a spring 140 is provided between the stepped portion 129 and the first ferrule 112. As a result, the first ferrule 112 can be prevented from being excessively inserted into the first stopper 110, and the first optical fiber 101 can be pressed toward the second optical fiber 102 by the spring 140. Even if the first optical fiber 101 is pulled, the distance between the first optical fiber 101 and the second optical fiber 102 hardly changes, and it becomes possible to stabilize these optical connections. Furthermore, the first stopper 110 has a hole portion 130 having a hole at the tip. As a result, the ferrule cover 115 can be firmly engaged with the first stopper 110 and the separation of the ferrule cover 115 and the first stopper 110 can be suppressed, so that the tensile characteristics of the communication light visualization cord 100 are improved. It becomes possible.

  Similarly, the second stopper 111 is made of brass, stainless steel or the like having a high hardness in a hollow cylindrical shape, and is attached to the distal end portion of the second crimping ring 109. As a result, the second stopper 111 is difficult to deform, and the second stopper 111 and the first stopper 110 can be firmly fixed via the ferrule cover 115. That is, the second stopper 111 and the first stopper 110 are difficult to separate from each other without relying on the second strength member 119 or the first strength member 116. Further, the second stopper 111 has a groove portion 128 formed by forming a groove on the outer peripheral surface. Accordingly, since the second strength member 119 can be securely sandwiched between the second crimping ring 109 and the second stopper 111, the second boot 107 and the second boot 107 are connected even if the communication light visualization cord 100 is pulled. Since the caulking ring 109 is difficult to separate, the tensile property of the communication light visualization cord 100 can be improved. The second strength member 119 is made by twisting Kepler fibers having high tensile strength into a yarn shape. The second stopper 111 has a step portion 129 formed by forming a step on the inner peripheral surface. Thereby, since it can suppress that the 2nd ferrule 113 is inserted in the 2nd stopper 111 excessively, even if the 2nd optical fiber 102 is pulled, between the 2nd optical fiber 102 and the 1st optical fiber 101 The distance between them hardly changes, and it becomes possible to stabilize these optical connections. Furthermore, the second stopper 111 has a hole portion 130 having a hole at the tip. Thereby, since the ferrule cover 115 can be firmly engaged with the second stopper 111 and the separation of the ferrule cover 115 and the second stopper 111 can be suppressed, the tensile characteristics of the communication light visualization cord 100 are improved. It becomes possible.

  As shown in FIG. 6, the first ferrule 112 includes a ferrule body 131 formed by forming zirconia or the like that is transparent to communication light (leakage light) into a hollow cylinder, and brass or stainless steel having high hardness. And a flange portion 132 that holds the ferrule body 131. The first ferrule 112 is held by the first stopper 110 and accommodates the distal end portion of the first optical fiber 101. More specifically, the flange portion 132 of the first ferrule 112 is held by the first stopper 110 and the tip portion of the first optical fiber 101 is accommodated in the ferrule body 131 of the first ferrule 112. The flange portion 132 has a step portion 134 formed with a step on the outer peripheral surface and a step portion 135 formed with a step on the inner peripheral surface. As a result, it is possible to suppress the flange portion 132 from being excessively inserted into the first stopper 110 and to suppress the ferrule body 131 from being excessively inserted into the flange portion 132. Even if it is pulled, the distance between the first optical fiber 101 and the second optical fiber 102 hardly changes, and it becomes possible to stabilize these optical connections. Further, the inner peripheral surface of the rear end of the ferrule body 131 is a chamfered portion 136, and the inner peripheral surface of the rear end of the flange portion 132 is a chamfered portion 137. Thereby, it becomes possible to facilitate the insertion of the first optical fiber 101 into the ferrule body 131 and the flange portion 132.

  Similarly, the second ferrule 113 is formed of a ferrule body 131 formed of zirconia or the like that is transparent to communication light (leakage light) into a hollow cylindrical shape, and brass or stainless steel having high hardness is formed into a hollow cylindrical shape. And a flange portion 132 for holding the ferrule main body 131. The second ferrule 113 is held by the second stopper 111 and accommodates the tip of the second optical fiber 102. More specifically, the flange 132 of the second ferrule 113 is held by the second stopper 111 and the tip of the second optical fiber 102 is housed in the ferrule body 131 of the second ferrule 113. The flange portion 132 has a step portion 134 formed with a step on the outer peripheral surface and a step portion 135 formed with a step on the inner peripheral surface. Accordingly, it is possible to suppress the flange portion 132 from being excessively inserted into the second stopper 111 and to suppress the ferrule body 131 from being excessively inserted into the flange portion 132. Even if it is pulled, the distance between the second optical fiber 102 and the first optical fiber 101 hardly changes, and these optical connections can be stabilized. Further, the inner peripheral surface of the rear end of the ferrule body 131 is a chamfered portion 136, and the inner peripheral surface of the rear end of the flange portion 132 is a chamfered portion 137. As a result, the second optical fiber 102 can be easily inserted into the ferrule body 131 and the flange portion 132.

  As shown in FIG. 7, the split sleeve 114 is formed by forming zirconia or the like that is transparent to communication light (leakage light) into a hollow cylindrical shape having slits 138, and includes a first ferrule 112 and a second ferrule. 113. As a result, the optical axis can be appropriately arranged at a desired position between the first optical fiber 101 and the second optical fiber 102, so that the light can be transmitted between the first optical fiber 101 and the second optical fiber 102. It is possible to form the light extraction unit 133 that appropriately shifts the axis and extracts part of the communication light transmitted through the optical communication path 103 as leakage light. The structure of the light extraction unit 133 is not particularly limited, and in addition to shifting the optical axis between the first optical fiber 101 and the second optical fiber 102, A part of communication light transmitted through the optical communication path 103 can be taken out as leakage light by utilizing the core diameter difference with the two optical fibers 102.

  As shown in FIG. 8, the ferrule cover 115 is formed by molding a methacrylic resin or the like that is transparent to communication light (leakage light) into a hollow cylindrical shape, and is attached between the first stopper 110 and the second stopper 111. The first ferrule 112 and the second ferrule 113 are accommodated together with the split sleeve 114. Thereby, the communication light visualization structure including the light extraction unit 133 can be protected. Further, the ferrule cover 115 has a protrusion 139 formed by forming a protrusion on the outer peripheral surface. Accordingly, the ferrule cover 115, the first stopper 110, and the second stopper 111 can be firmly fixed by engaging the protrusion 139 of the ferrule cover 115 with the hole 130 of the first stopper 110 and the second stopper 111. It becomes possible.

  The presence or absence of communication light can be visually confirmed by leaking light extracted from the light extraction unit 133 by, for example, a method of detecting with a light receiving element or a method of converting to visible light and outputting. In addition, when communication light is visible light, leakage light can also be confirmed directly visually.

  According to the communication light visualization code 100 described so far, the communication light visualization structure is installed in an optical communication-related facility in which the communication light visualization structure 100 is not implemented only by replacing the existing patch cord with the communication light visualization code 100 for each port. Therefore, the communication light visualization structure can be easily installed in optical communication related equipment that does not implement the communication light visualization structure without significant system change or simultaneous communication of multiple ports. It becomes possible.

  Further, according to the communication light visualization cord 100, the tensile strength of the communication light visualization cord 100 is improved by using the first tensile body 116 and the second tensile body 119. It becomes possible to endure.

100 communication light visualization code 101 first optical fiber 102 second optical fiber 103 optical communication path 104 first optical cord 105 second optical cord 106 first boot 107 second boot 108 first caulking ring 109 second caulking ring 110 1st stopper 111 2nd stopper 112 1st ferrule 113 2nd ferrule 114 Sleeve 115 Ferrule cover 116 1st tensile body 117 Optical fiber strand 118 Protective layer 119 2nd tensile body 120 Thickening part 121 Claw part 122 Chamfer part 123 Corner portion 124 Step portion 125 Groove portion 126 Step portion 127 Chamfer portion 128 Groove portion 129 Step portion 130 Hole portion 131 Ferrule main body 132 Flange portion 133 Light extraction portion 134 Step portion 135 Step portion 136 Chamfer portion 137 Chamfer portion 138 Slit 139 Projection Part 140 Spring

Claims (1)

Communication light visualization code for realizing visualization of communication light transmitted through the optical communication path for the purpose of visual confirmation of communication status in the optical communication path formed by optically connecting the first optical fiber and the second optical fiber Because
A first optical cord that contains the first optical fiber and is formed by molding a polyvinyl chloride resin into a hollow cylindrical shape ;
A second optical cord in which the second optical fiber is accommodated and formed by molding a polyvinyl chloride resin into a hollow cylindrical shape ;
A first boot attached to the tip of the first optical cord and formed by molding a polyester elastomer into a hollow cylinder ;
A second boot that is attached to the tip of the second optical cord and is formed by molding a polyester elastomer into a hollow cylinder ;
A first caulking ring that is attached to the tip of the first boot and is formed of aluminum in a hollow cylindrical shape ;
A second caulking ring attached to the tip of the second boot and formed by molding aluminum into a hollow cylinder ;
A first stopper attached to the tip of the first caulking ring and formed of brass or stainless steel in a hollow cylindrical shape ;
A second stopper that is attached to the tip of the second caulking ring and is formed of brass or stainless steel in a hollow cylindrical shape ;
The first ferrule body, which is held by the first stopper and accommodates the tip of the first optical fiber, is formed of zirconia in a hollow cylindrical shape, and holds the first ferrule body, and brass or stainless steel is hollow. A first ferrule having a first flange portion formed into a cylindrical shape ,
The second ferrule main body formed by forming the hollow end of the zirconia and the second ferrule main body held by the second stopper and holding the second ferrule main body, and brass or stainless steel hollow. A second ferrule having a second flange portion formed into a cylindrical shape ,
The first ferrule and the second ferrule are held , and a split sleeve formed by molding zirconia into a hollow cylinder having a slit ;
A ferrule cover that is attached between the first stopper and the second stopper and in which the first ferrule and the second ferrule are accommodated together with the split sleeve;
With
The first optical fiber and the second optical fiber are optically connected via a light extraction unit that extracts a part of the communication light transmitted through the optical communication path as leakage light,
The ferrule cover all SANYO molded methacrylic resin which is transparent to the communication light to the hollow cylinder,
The first optical cord contains a first tensile body together with the first optical fiber,
The second optical cord contains a second tensile body together with the second optical fiber,
The first tensile body has a tip portion sandwiched between the first crimping ring and the first stopper,
The second strength member has a tip portion sandwiched between the second crimping ring and the second stopper,
The first strength member and the second strength member, the communication light visualization code, characterized in der Rukoto that twisting Kepler fiber thread.

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