JP4305490B2 - Light outlet - Google Patents

Description

  The present invention relates to an optical outlet for connecting an optical cable.

  Conventionally, an optical cable plug that is embedded in a construction material such as a wall surface and is wired in advance on the back side of the construction material is connected in advance, and the optical cable plug on the communication device side is connected from the front surface side of the construction material. An optical outlet that is plugged in is provided (see, for example, Patent Document 1).

  Such an optical outlet is, for example, disposed in an embedding box embedded in a construction material, but an optical cable previously wired on the back side of the construction material is introduced into the embedding box, and the optical cable After connecting the plug at the end to the optical outlet, when storing the extra length of the optical cable in the empty space in the embedded box, if the optical cable is bent with a radius of curvature smaller than the allowable minimum radius of curvature of the optical cable, There is a possibility that the transmission loss of the above will deteriorate. Therefore, as shown in FIGS. 8 and 9, the extra length of the optical cable is wound around the winding member with a radius of curvature larger than the allowable minimum radius of curvature, so that extra length processing can be performed without causing deterioration in transmission loss. An optical outlet is provided.

  This optical outlet is formed in a shape and size that can be attached to a mounting frame for a large-angle continuous wiring apparatus standardized by JIS, etc., and the entire front surface is open and partly from the upper surface to the rear surface. A substantially box-shaped body 61 having an opening, a cover 62 pivotally supported in an opening provided in the front surface of the body 61, and an SMI-type optical connector 63 (optical) attached to the back side of the cover 62 And a winding member 64 attached to the back surface of the body 61 so as to be positioned on the back side with respect to the optical connector 63.

  The winding member 64 includes a substantially cylindrical winding body 65 on the back side, and includes a guide section 66 having an arcuate cross section that curves downward from the upper side of the winding body 65 toward the front. The left and right side edges of the portion 66 are formed in an arc shape so as to become narrower toward the front side (see FIG. 8D). Guide walls 67 and 67 project upward from the left and right side edges of the guide portion 66, and the guide walls 67 and 67 are arcuate so that the distance between the guide walls 67 and 67 increases toward the back. Is curved. Further, both guide walls 67 and 67 extend to the outside of the winding drum portion 65 in the left-right direction, and a gap is provided between the lower end of the guide wall 67 and the peripheral surface of the winding drum portion 65. An elastic holding piece 68 is projected.

Here, when connecting the plug of the optical cable previously wired on the back side of the construction material to the optical outlet, the plug provided at the end of the optical cable is connected to the optical connector 63, and then the plug connected to the optical connector 63 is connected. After the optical cable extending from the cable is introduced into the winding drum portion 65 through the gap between the guide walls 67, 67, the extra length of the optical cable is wound around the winding drum portion 65 to perform extra length processing. Since the optical cable is not wound with a radius of curvature smaller than the allowable minimum radius of curvature, the optical cable can be stored compactly without deteriorating transmission loss.
JP 2005-234383 A

  In the optical outlet shown in FIG. 8 and FIG. 9 described above, when the optical cable previously wired on the back side of the construction material is connected to the optical outlet, the optical cable connected to the optical connector 63 is pulled out to the upper side, and the guide 66 is provided. Bend backward along the guide wall 67, after passing through the gap between the guide walls 67, 67, twist the optical cable in either direction left and right to project the tip side in the circumferential direction of the winding body 65, Since it was wound around the winding body 65, the optical cable was wound in a twisted state. Since this optical cable is not supported at the starting point where the winding body 65 starts to be wound, the optical cable is twisted or externally applied to the root of the optical cable (that is, the connecting portion between the plug connected to the optical connector 63 and the cable portion). May be added, and transmission loss may be deteriorated.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an optical outlet in which stress applied to a connecting portion between a plug connected to an optical connector and a cable portion is reduced. It is in.

In order to achieve the above object, the invention of claim 1 is characterized in that an outlet body embedded in an embedding hole provided in the construction material, and housed in the outlet body, opened to the surface side of the construction material. The first plug connection port to which the plug provided at the end of the optical cable is inserted and connected from the front side of the construction material and the plug provided at the end of the other optical cable previously wired to the back side of the construction material are inserted. A second plug connection port to be plugged in, an optical connection tool for optically connecting between plugs plugged into both plug connection ports, and disposed on the back side with respect to the optical connection tool, A winding drum portion wound with a radius of curvature greater than the allowable minimum radius of curvature of the optical cable connected to the second plug connection port, and an outer jacket of the optical cable wound around the winding drum portion. Winding having a cable holding part to be sandwiched between the attached surfaces The winding member has a rectangular plate shape in plan view and a right and left corner on one end in the longitudinal direction rounded in an arc shape, and from the outer peripheral edge of the substrate portion toward the back side. A side wall portion protruding in the left and right sides of the side wall portion on the other end side in the longitudinal direction, and a guide wall having a circular arc-shaped curved surface projecting toward the other end side in the longitudinal direction, and the front side of the left and right guide walls Cable holding pieces that protrude forward from the inner edge of the edge with the same radius of curvature as the guide wall, and the guide walls on both the left and right sides are projected to the front and back sides of the board. In addition, it is provided so as to be continuous to the left and right side portions of the side wall portion, and the side wall portion and a part of the guide wall constitute a winding drum portion, and is connected to the second plug connection port by the cable pressing pieces on both sides. Light at the site between the plug and the winding drum With sandwich the jacket of Buru, optical cable which is held by the cable holding piece, characterized in that it is guided to the sidewall portion by being bent along the guide wall.

The invention of claim 2 is characterized in that, in the invention of claim 1 , the winding member is provided with display means for displaying the winding position of the optical cable along the position where the optical cable is wound.

According to a third aspect of the present invention, in the invention according to any one of the first and second aspects, the optical cable is wound around the winding member a plurality of times, and the winding of the rear side of the portion of the optical cable held by the cable holding portion is performed. A temporary holding means for temporarily holding the attachment portion is provided on the winding member.

  According to the first aspect of the present invention, there is provided a cable pressing portion for sandwiching the jacket of the optical cable between the plug connected to the second plug connection port of the optical connector and the winding body portion of the winding member. Therefore, by fixing the base of the optical cable (that is, the connection part with the plug) with the cable holding part, external force is applied to the connection part between the optical cable and the plug, and stress can be prevented from being applied to the optical cable. Therefore, it is possible to suppress the deterioration of the optical transmission loss that occurs.

Moreover, since the cable pressing pieces are formed to protrude forward from the inner side of the front side edge of the guide walls on the left and right sides, respectively, with the same radius of curvature as the guide walls, the optical cable extends backward from the cable pressing pieces. Can be bent along the surface of the guide wall to guide it to the winding surface, and no force that twists the optical cable is applied to the optical cable at this time. Therefore, it is possible to prevent the transmission loss of light from deteriorating due to excessive force.

According to the invention of claim 2 , by winding the optical cable in accordance with the display of the display means, it is possible to easily perform the winding operation of the optical cable and to prevent the winding direction from being mistaken.

According to the invention of claim 3 , since the part of the optical cable wound around the winding member around the winding member is temporarily held by the temporary holding means, the optical cable can be prevented from expanding in diameter, and the optical outlet can be When being embedded in the construction material, it is possible to prevent the extra length of the optical cable from being scattered and obstruct the storing work, and the construction work can be easily performed.

  Below, one Embodiment of the optical outlet based on this invention is described based on FIGS. In the present embodiment, description will be made by taking as an example a wiring device provided with an optical outlet and a modular outlet according to the present invention. In the following description, unless otherwise specified, the vertical and horizontal directions are defined in the direction shown in FIG. 3A, and the front side in FIG. Accordingly, the left end in FIG. 3B is the rear end.

  As shown in FIGS. 1 and 2, the wiring device 1 has a rectangular frame-shaped mounting frame 4 having a rectangular opening window 4a at the center, and a front surface exposed from the opening window 4a of the mounting frame 4. The optical outlet 2 and the modular outlet 3 attached to the attachment frame 4 are provided. In the following description, the dimension occupying 1/3 of the longitudinal direction (vertical direction in FIG. 1) of the opening window 4a of the mounting frame 4 (in other words, three are arranged in the longitudinal direction of the opening window 4a and attached to the mounting frame 4). (Possible dimension) is defined as one module dimension.

  First, the attachment frame 4 used for attaching wiring devices such as the optical outlet 2 and the modular outlet 3 to a construction material such as a wall material will be described. The mounting frame 4 is for a single large-angle continuous wiring apparatus standardized by, for example, the JIS standard, and is an opening window that exposes the front surface of the wiring apparatus in the center using, for example, an insulating synthetic resin. It is formed in a rectangular frame shape having 4a. As shown in FIGS. 1 to 3, the attachment frame 4 is a lateral frame that connects long frame pieces 40, 40 parallel to each other, and one end portions and the other end portions of the pair of frame pieces 40, 40. The pieces 41 and 41 are integrally provided, and a central portion surrounded by the frame pieces 40 and 40 and the horizontal pieces 41 and 41 is an opening window 4a. In each of the frame pieces 40, 40, two sets of mounting holes 42 used for mounting the wiring device are formed. Further, a box hole 41a through which a box screw (not shown) for attaching the mounting frame 4 to an embedded box (not shown) embedded in the construction material is inserted in the central portion of each horizontal piece 41, 41. And a plate screw hole 41b into which a plate screw (not shown) for attaching a plate (not shown) to the front side of the mounting frame 4 is screwed. Of course, such a mounting frame 4 may be based on other standards. Further, the mounting frame 4 is not limited to a rectangular frame shape, and may be a disk shape having a rectangular opening window 4a, for example, as long as it has an opening window 4a for mounting a wiring device. .

  Next, the optical outlet 2 and the modular outlet 3 attached to the attachment frame 4 will be described.

  The modular outlet 3 is an embedded wiring device for connecting a modular cable (not shown) for a telephone line. As shown in FIGS. A modular body 30 having a modular cable insertion port 31 on the front side and a modular plug inserted from the insertion port 31 are detachably connected. And a modular jack (not shown).

On the other hand, as shown in FIGS. 1 and 2, the optical outlet 2 includes an outlet body 10 formed in two module dimensions, an optical connector 11 (adapter) housed in the outlet body 10, and an outlet body. 10 is provided with a back cover 12 that holds the optical connector 11 between the rear surface 10, a winding member 13 that is attached to the back cover 12 and winds and holds the extra length of the optical cable, and the optical connector 11. Of the individual plug connection ports 15a and 15b, the plug connection port 15b is detachably attached to the plug connection port 15b to which the optical cable 5 wired in advance on the back side of the construction material is connected. A dustproof cover 14 that is closed is provided as a main component. As shown in FIG. 5, the optical cable 5 includes a plug 50 having a connection ferrule 51 at its end, and the plug 50 and the cable portion 53 are fixed to each other so that the connection portion between the cable portion 53 and the plug 50 is provided. A square tubular grip 52 is provided to relieve the stress applied to the body. In this embodiment, the optical outlet 2 will be described by taking a single-core type as an example, but a two-core type to which two optical cables can be connected may be used.

  First, the optical connector 11 will be briefly described. The optical connector 11 is an adapter of F04 type (also referred to as SC type) defined by JIS, for example, and includes a rectangular tube-shaped housing 15 having both ends opened and a ferrule 51 of a plug 50 detachably fitted at both ends. The sleeve 16 is accommodated in the housing 15 so that both ends thereof face both side openings of the housing 15. Accordingly, the optical connector 11 is configured to have the first and second plug connection ports 15a and 15b on both ends, and the first plug connection port (hereinafter abbreviated as a plug connection port) 15a. While facing the insertion port 18b of the outlet body 10 obliquely downward, the second plug connection port (hereinafter abbreviated as a plug connection port) 15b is stored in the outlet body 10 with the diagonally upward direction. Is done. The receptacle 50 is configured by connecting the plug 50 of the optical cable 5 wired in advance to the back surface side of the construction material to the plug connection port 15b that opens to the back surface side of the outlet body 10. In addition, a flange portion 15c is formed integrally on the left and right side surfaces of the housing 15 of the optical connector 11 so as to protrude outward from an intermediate portion in the vertical direction, and a portion above the flange portion 15c is located on the lower side. It is narrower than the part.

  Further, when the plug provided at the end portion of the optical cable from the surface side of the construction material is not connected to one plug connection port 15a of the optical connector 11, the plug connection port 15a is closed, and the second A pair of opening / closing doors 17 are provided for preventing light of the optical cable connected to the plug connection port 15b from leaking to the outside through the plug connection port 15a (see FIGS. 3A and 3C). The pair of opening / closing doors 17 is attached so as to be swingable in the plug insertion direction into the plug connection port 15a, and is attached in a direction opposite to the insertion direction using a leaf spring (not shown). It is energized.

  Therefore, when the plug is connected to the optical connector 11 from the surface side of the construction material, the pair of opening and closing doors 17 and 17 are pressed against the urging force of the leaf spring with the plug of the optical cable, thereby opening and closing the door 17. , 17 and the plug is inserted into the optical connector 11 so that the ferrule of the plug is fitted into the sleeve 16, whereby the plug of the optical cable is connected to the optical connector 11. On the other hand, when the optical cable is pulled out from the optical connector 11, the pair of opening / closing doors 17, 17 are moved by the urging force of the leaf spring, thereby closing the plug connection port 15 a.

  As shown in FIGS. 1 to 3, the outlet body 10 is formed of a synthetic resin and has a module size of two, and has a box shape with an open rear surface. When 10 is attached to the attachment frame 4, the bulging part 18 which protrudes ahead from the opening window 4a of the attachment frame 4 is integrally formed. As shown in FIGS. 3B and 3C, a downwardly inclined surface 18a whose surface direction is obliquely downward is formed at the lower portion of the bulging portion 18, and is formed at the center of the downwardly inclined surface 18a. Is provided with an insertion port 18b communicating with the plug connection port 15a of the optical connector 11. Further, as shown in FIGS. 2 and 5, a plurality of positioning ribs 19 for abutting the front side of the housing 15 and positioning the optical connector 11 are integrally provided on the rear surface side of the bulging portion 18. ing.

  As shown in FIG. 1, two sets of mounting claws 10 a are formed on each of the left and right side surfaces of the outlet body 10, with two pairs of mounting claws 10 a each being engaged with the pair of mounting holes 42 of the mounting frame 4. Yes. In addition, as shown in FIG. 1, a notch portion 10 b into which the grip portion 52 of the optical cable 5 is inserted is formed on the upper surface of the outlet body 10, and in the vicinity of the notch portion 10 b on the inner surface of the outlet body 10. In this case, the holding portion 52 of the optical cable 5 is fitted, and a fixing rib 10 c for fixing the holding portion 52 is provided. Further, locking ribs 10e having locking holes 10d are formed on the left and right inner side surfaces of the lower side portion of the outlet body 10, respectively.

  Here, when the optical connector 11 is stored in the outlet body 10, the back cover 12 is used to fix the optical connector 11 to the outlet body 10. The back cover 12 is made of a synthetic resin molded product as shown in FIGS. 1 and 2, and is provided with a flat plate portion 20 having a longitudinal direction in the left-right direction and a front side of the flat plate portion 20 for positioning the outlet body 10. An abutment portion 21 that sandwiches the housing 15 of the optical connector 11 between the rib 19 and a square cylindrical support base portion 22 that protrudes rearward from the back surface of the flat plate portion 20 and supports the winding member 13. In addition, locking portions 20a that are fitted into the locking holes 10d of the outlet body 10 are integrally formed on both side portions in the left-right direction on the rear surface side of the flat plate portion 20. Further, the contact portion 21 is formed with a step portion 21 a that engages with the flange portion 15 c of the housing 15. Furthermore, the both ends of the flat plate part 20 in the left-right direction on the front side are in contact with the flange part 15c of the optical connector 11 so that the optical connector 11 is connected to the peripheral edge of the insertion port 18b in the outlet body 10. A pair of movement-preventing ribs 20b, 20b that project the optical connection tool 11 in the longitudinal direction and project are integrally provided. Further, the movement preventing ribs 20b, 20b are configured to contact the optical connector 11 in the left-right direction, thereby restricting the optical connector 11 from moving in the left-right direction. In addition, elastic locking pieces 22a that can be bent in the left-right direction by forming notches opened on the rear end side are provided at the rear portions of the left and right side pieces of the support base 22, and each elastic locking piece 22a. A locking claw 22b that protrudes outward is provided at the tip of the projection.

  The winding member 13 is made of a synthetic resin molded product as shown in FIG. 1 and FIG. 2, and is a substantially rectangular plate shape whose plan view is long in the vertical direction, and the left and right corners are arcuate. A rounded substrate portion 23, a side wall portion 24 projecting from the outer peripheral edge of the substrate portion 23 toward the back side, and a guide wall having a semicircular section provided on the left and right side portions of the upper side wall portion 24 and projecting upward. 25 and 25 are integrally provided. The left and right guide walls 25, 25 are formed so as to protrude to the front side of the board portion 23, and cable holding pieces having the same curvature radius as the guide walls 25 are formed from the inner side portions of the front side edges of the both guide walls 25, 25. 25a and 25a (cable pressing part) are formed to protrude forward. That is, the cable pressing pieces 25a and 25a are provided inside the winding surface of the winding drum portion (consisting of the side wall portion 24 and a part of the guide wall 25) in the winding member 13, and the cable pressing pieces 25a and 25a Guide walls 25, 25 each having a curved surface with an arcuate cross section are provided on both sides of the cable pressing pieces 25a, 25a. In the winding member 13, the curvature radius of the curved portion (the curved portion of the side wall portion 24 and the guide wall 25) around which the optical cable 5 is wound is set to be larger than the allowable minimum curvature radius of the optical cable 5.

  A pair of strip-shaped cable holding pieces 26 arranged in parallel with the left and right side wall portions 24 are connected to the left and right side edges of the substrate portion 23 via a connecting portion 26a. In addition, a strip-shaped cable holding piece 28 facing the lower side of the side wall part 24 with a gap is connected to the lower side edge of the substrate part 23 via a connecting part 28a. And the side wall portion 24 are set to dimensions that allow the cable portion 53 of the optical cable 5 to be inserted. Further, a strip-shaped temporary holding piece 27 (temporary holding means) is projected from the front end side of the connecting portion 26a toward the front. Further, a pair of locking holes 23a into which the pair of elastic locking pieces 22a of the back cover 12 described above are inserted are provided in the lower side of the substrate portion 23, respectively.

  The optical outlet 2 is composed of the above-described members, and these are assembled as follows. That is, as shown in FIG. 5, the optical connector 11 is housed inside the outlet body 10 with one plug connection port 15a facing diagonally downward and facing the outside of the outlet body 10 from the insertion port 18b. To do. At this time, the positioning rib 19 provided on the inner side surface of the outlet main body 10 contacts the front side of the housing 15 of the optical connector 11. Thereafter, the back cover 12 is moved closer to the outlet body 10 from the back side of the outlet body 10 and the locking portion 20a of the back cover 12 is fitted into the locking hole 10d of the outlet body 10 so that the back cover 12 is connected to the outlet body 10. Attached to. At this time, since the housing 15 of the optical connector 11 is sandwiched between the positioning rib 19 of the outlet body 10 and the contact portion 21 of the back cover 12, the housing 15 is positioned in the front-rear direction. This prevents the outlet body 10 from falling off. Further, the movement preventing ribs 20b, 20b of the back cover 12 abut on the flange portion 15c of the optical connector 11, so that the optical connector is connected to the peripheral edge portion of the insertion port 18b in the downward inclined surface 18a of the outlet body 10. 11, the optical connector 11 is positioned in the longitudinal direction, and the movement preventing ribs 20b and 20b are in contact with the left and right side surfaces of the housing 15, whereby the housing 15 is positioned in the left and right direction. Therefore, when the optical cable 5 is connected to the optical connector 11, the optical connector 11 does not wobble and the optical cable 5 can be easily connected.

  Moreover, the winding member 13 can be detachably attached to the back side of the back cover 12. That is, from the back side of the back cover 12, the winding member 13 is brought close to the back cover 12 with the temporary holding piece 27 in front, and the elastic locking pieces 22 a and 22 a provided on the support base 22 of the back cover 12 are wound up. Inserting into the locking holes 23a, 23a provided in the substrate portion 23 of the member 13, respectively, and locking the locking claw 22b at the tip of the elastic locking piece 22a to the hole edge on the back side of the locking hole 23a. Then, the winding member 13 is attached to the back cover 12. At this time, the lower side surface 22c and the upper side surface of the support base 22 are engaged with ribs 23b and 23b provided on the front side of the substrate 23, respectively, and the notch groove 22d provided on the upper side of the support base 22 is formed on the substrate. By engaging with the rib 23 c provided on the front surface of the portion 23, the winding member 13 can be attached to the back cover 12 without rattling. The take-up member 13 is detachable from the back cover 12, and an external force is applied to the distal end portion of the elastic locking piece 22a protruding to the back side through the locking hole 23a so that the elastic locking piece 22a is attached. By bending in the direction approaching each other, the locking state of the locking claw 22b and the locking hole 23a of the elastic locking piece 22a is released, so that the winding member 13 can be removed from the back cover 12. It has become.

  By the way, the wiring apparatus 1 is comprised by attaching the optical outlet 2 and the modular outlet 3 to the attachment frame 4, and the optical outlet 2 and the modular outlet 3 are attached with respect to the attachment frame 4 as follows. That is, in the modular outlet 3, as shown in FIGS. 1 and 3, the pair of mounting claws 32 provided on the left and right side portions of the container body 30 are inserted into the pair of mounting holes 42 located on the uppermost side of the mounting frame 4, respectively. The fitting frame 4 in a state where the front boss portion 33 protrudes forward from the opening window 4a of the mounting frame 4 (in other words, the boss portion 33 is exposed from the opening window 4a to the front surface) by fitting the concave and convex portions. Attached to. Then, the optical outlet 2 uses the remaining space in the opening window 4a of the mounting frame 4 to provide two sets of mounting claws 10a provided on the left and right sides of the outlet body 10, and the remaining four sets of mounting holes of the mounting frame 4. 42 is mounted in a state in which the bulging portion 18 protrudes forward from the opening window 4a of the mounting frame 4 (in other words, the bulging portion 18 is exposed to the front from the opening window 4a) by fitting the projections and recesses to each other. It is attached to the frame 4.

  Thus, the wiring device 1 shown in FIGS. 3 to 5 is obtained, and the wiring device 1 is embedded in the construction material 70 as follows. First, an embedding hole 71 having an appropriate size is formed in a construction material 70 such as a wall material, and then the embedding box (not shown) is placed on the back side of the construction material 70 so as to face the embedding hole 71. ). Next, through a knockout hole formed in the embedding box, a telephone line (not shown) wired in advance on the back side of the construction material 70 is introduced into the embedding box, and this telephone line is further inserted into the embedding hole 71. After being pulled out from the front side of the construction material 70, it is inserted into a wire insertion hole provided in the back surface of the body 30 of the modular outlet 3, and is connected to a quick connection terminal (not shown) housed inside the body 30. Connecting.

  Further, the optical cable 5 wired in advance on the back side of the construction material 70 is introduced into the embedding box through the knockout hole formed in the embedding box, and the optical cable 5 is further inserted into the surface of the construction material 70 from the embedding hole 71. The plug 50 provided at the end of the optical cable 5 is connected to the plug connection port 15 b of the optical connector 11. Here, when attaching the plug 50 of the optical cable 5 to the optical connector 11, it is necessary to remove the winding member 13 in advance. Also, a dustproof cover 14 is attached to the plug connection port 15b of the optical connector 11 to prevent dust from entering the housing 15 before construction, such as during storage or transportation. After the removal, the plug 50 of the optical cable 5 is connected to the plug connection port 15 b, and then the winding member 13 is fixed to the support base portion 22 of the back cover 12. At this time, the optical cable 5 connected to the plug connection port 15b is inserted into the notch 10b and the fixing rib 10c of the outlet main body 10 as shown in FIG. Guide walls 25, 25 are arranged to prevent the optical cable 5 from coming off.

Here, before the mounting frame 4 to which the optical outlet 2 and the modular outlet 3 are attached is fixed to the construction material 70, the extra length processing of the optical cable 5 is performed. That is, the root of the cable portion 53 extending from the plug 50 (the connection portion of the cable portion 53 with the plug 50) is introduced into the gap 25b between the cable pressing pieces 25a and 25a, and the root of the cable portion 53 is connected to the cable pressing piece. The cable part 53 is fixed by being clamped between 25a and 25a. Thereafter, the cable portion 53 extending rearward from the gap 25b between the cable pressing pieces 25a and 25a is guided to the side wall portion 24 along the peripheral surface of any of the guide walls 25, and along the peripheral surface of the side wall portion 24. The cable part 53 is wound once. At this time, the cable portion 53 is inserted between the cable holding pieces 26 and 28 and the side wall portion 24 so that the cable portion 53 is prevented from coming off. Thereafter, as shown in FIG. 7, the cable portion 53 is crossed at the upper portion of the winding member 13, the cable portion 53 is passed inside the temporary holding piece 27, and the extra length portion of the cable portion 53 is passed to the winding member 13. by multiple winding, and performs the extra length handling of the cable 53.

  After the extra length processing of the optical cable 5 is performed as described above, the wiring device 1 is installed by screwing the box screws respectively inserted into the box holes 41a and 41a of the mounting frame 4 into the screw holes of the embedding box. It is embedded in the construction material 70. Further, a plate (not shown) is attached to the front side of the mounting frame 4, and the front surfaces of the optical outlet 2 and the modular outlet 3 are exposed from the window hole of the plate.

  As described above, in the optical outlet 2 of the present embodiment, the outer sheath (cable portion) of the optical cable 5 between the plug connected to the plug connection port 15b of the optical connector 11 and the side wall portion 24 of the winding member 13 is used. 53) and the cable pressing pieces 25a, 25a for holding the cable portion 53) are provided, and the base of the cable portion 53 is fixed by the cable pressing pieces 25a, 25a, so that an external force is applied to the connection portion between the cable portion 53 and the plug 50. It is possible to prevent stress from being applied to the optical cable 5.

  The cable pressing pieces 25a and 25a are provided inside the winding surface of the winding drum portion (consisting of the side wall portion 24 and a part of the guide wall 25) in the winding member 13, and are wound from the cable pressing pieces 25a and 25a. Since guide walls 25 and 25 each having a curved surface with an arcuate cross section are provided in the winding direction with respect to the cable pressing pieces 25a and 25a, they extend rearward from the cable pressing pieces 25a and 25a. The cable portion 53 can be bent along the surface of the guide wall 25 and guided to the side wall portion 24. When the extra length portion of the cable portion 53 is wound around the side wall portion 24, a force that twists the cable portion 53 is applied to the cable portion. Therefore, it is possible to prevent the transmission loss of light from deteriorating due to excessive force applied to the cable portion 53. Here, on the surface of the guide wall 25, as shown in FIG. 7, a position display line 25c (display means) indicating the winding position of the cable portion 53 is formed by an appropriate method such as die stamping or printing. Therefore, by winding the cable portion 53 along the position display line 25c, the winding operation of the cable portion 53 can be easily performed.

  Of the cable portion 53 wound around the winding member 13, the portion wound around the side wall portion 54 is held between the cable holding pieces 26, 28 and the side wall portion 54, so that the cable portion 53 extends from the winding body portion. It can be prevented from coming off. Further, the portion of the cable portion 53 wound around the winding member 13 from the second round onward can be prevented from expanding the diameter of the cable portion 53 by passing through the inside of the temporary holding pieces 27, 27. When the outlet 2 is housed in the embedded box, it is possible to prevent the extra length of the cable portion 53 from being scattered and obstruct the housing work, thereby facilitating the construction work.

  It should be noted that a wide variety of different embodiments can be configured without departing from the spirit and scope of the present invention, and the present invention is not limited to a specific embodiment.

It is the disassembled perspective view which looked at the wiring apparatus using the optical outlet of this embodiment from the front. It is the disassembled perspective view which looked at the wiring apparatus using the same from the back. The wiring apparatus using the same is shown, (a) is a front view, (b) is a left side view, and (c) is a bottom view. It is a rear view of the wiring apparatus using the same. The wiring apparatus using the same as above is shown, and is a cross-sectional view taken along the line AA of FIG. The wiring apparatus using the same as above is shown, (a) is an external perspective view seen from the rear, and (b) is an external perspective view seen from the front. It is a top view of the wiring apparatus using the same. The conventional optical outlet is shown, (a) is a front view, (b) is a BB sectional view, (c) is a rear view, and (d) is a top view. The optical outlet same as the above is shown, (a) is an external perspective view seen from the rear, (b) is an external perspective view seen from the front.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Wiring apparatus 2 Optical outlet 3 Modular outlet 4 Mounting frame 10 Outlet main body 11 Optical connector 12 Back cover 13 Winding member 14 Dust-proof cover 15a 1st plug connection port 15b 2nd plug connection port 24 Side wall part (winding body part) )
25 Guide wall 25a Cable holding piece (cable holding part)
26 Cable holding piece (cable holding part)

Claims (3)

An outlet body that is embedded in an embedding hole provided in the construction material, and a plug that is housed inside the outlet body, opens to the surface side of the construction material, and is provided at the end of the optical cable from the surface side of the construction material A first plug connection port to be plugged in and a second plug connection port into which a plug provided at the end of another optical cable previously wired on the back side of the construction material is plugged and connected. An optical connector that optically connects between plugs plugged into the plug connection port, and an extra length of an optical cable that is disposed on the back side of the optical connector and connected to the second plug connection port A winding body having a winding radius that is larger than the allowable minimum radius of curvature, and a cable holding portion that holds the outer sheath of the optical cable wound around the winding body between the winding surface of the winding body and the winding body. The winding member has a rectangular shape in plan view. A board portion that is round and rounded at the left and right corners on one end side in the longitudinal direction, a side wall portion that protrudes from the outer periphery of the board portion toward the back side, and a side wall portion on the other end side in the longitudinal direction. A guide wall that is provided on each of the left and right sides and protrudes to the other end in the longitudinal direction, and a front wall with the same radius of curvature as the guide walls, from the inner side of the front edge of the left and right guide walls. Cable guide pieces projecting toward the left and right, the guide walls on the left and right sides projecting from the front side and the back side of the board part, respectively, and continuous to the left and right side parts of the side wall part, respectively. The side wall portion and a part of the guide wall are provided to form the winding body portion, and the optical cable at a portion between the plug and the winding body portion connected to the second plug connection port by the cable pressing pieces on both sides. While holding the outer cover of the Optical cable which is held in Bull pressing pieces, light outlet, characterized in that it is guided to the sidewall portion by being bent along the guide wall.   2. The optical outlet according to claim 1, wherein the winding member is provided with display means for displaying a winding position of the optical cable along a position where the optical cable is wound.   An optical cable is wound a plurality of times around the winding member, and the winding member is provided with temporary holding means for temporarily holding a winding portion on the rear side of the portion held by the cable holding portion in the optical cable. The optical outlet according to any one of claims 1 and 2.

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