JP2017211528A - Optical terminal device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an optical terminal device capable of easily removing an optical fiber that has already been housed.SOLUTION: An optical terminal device includes a plurality of guide parts 41a-41d capable of housing an excess length part of an optical fiber by winding it, and has four elastic presser claws 49 extending from upper edges of the guide parts 41a-41d and being radially formed. In a normal condition, tips of the elastic presser claws 49 protrude into a groove formed between the plurality of guide parts, and when the elastic presser claws 49 are bent, the tips do not protrude into the groove. Therefore, when the elastic presser claws 49 are bent, the optical fiber can be easily removed from the groove between the guide parts, without interference of the elastic presser claws 49.SELECTED DRAWING: Figure 12

Description

  The present invention relates to an optical terminal device having a function of converting an optical signal input from an optical fiber into an electrical signal and outputting the electrical signal, and including an extra length storage unit for storing an extra length of an optical fiber introduced into a housing. is there.

  In recent years, with the spread of high-speed broadband communication services, communication services for connecting homes and transmitting stations with optical cables, for example, data communication services that provide integrated services such as home telephones, the Internet, and television. FTTH (Fiber To The Home) and optical cable television (CATV) are being implemented. Realization of this communication service requires an optical terminal device for demodulating an optical signal transmitted through an optical fiber by converting the optical signal into an optical-electrical signal and supplying the demodulated electric signal to a set-top box or a transmission line. Become. In the case of a general optical terminal device, there is an extra length storage unit that stores the extra length of the introduced optical fiber, and an optical receiver that converts the optical signal from the introduced optical fiber into an electrical signal and outputs it. Has been.

FIG. 17 is a perspective view showing the configuration of the conventional optical terminal device described in Patent Document 1, FIG. 18 is a perspective view showing the configuration of the extra length storage tray accommodated in the optical terminal device, and FIG. A top view showing the structure is shown in FIG.
As shown in FIG. 17, the conventional optical terminal device 100 includes a housing that includes a main body 102 and a lid 103 that is pivotally supported by the main body 102 so as to be opened and closed. FIG. 17 is a perspective view showing a configuration in a state where the lid 103 is opened. Three coaxial terminals 151 are provided in the lower half of the front plate 102a of the main body 102, optical fiber introduction holes 102f are formed on the left and right sides of the upper half of the front plate 102a, and a pair of engagements are provided between the optical fiber introduction holes 102f. A protrusion 102c is formed. A power cable 161 is led out from one side of the front plate 102a.
The lid 103 includes an upper surface plate 103a, and a first side surface plate 103b and a second side surface plate 103c that are formed upright from both sides of the upper surface plate 103a. An extending portion 103d extending forward is formed from the front side of the upper surface plate 103a, and an engaging piece 103e is formed at the tip of the extending portion 103d. When the lid portion 103 is closed, the engaging piece 103e becomes the main body portion. Engage with the engaging protrusion 102 c of 102. The first side plate 103b and a substantially rectangular holding piece 103f extending from the rear part of the lower edge of the second side plate facing the first side plate 103b are formed, and a hole formed in the holding piece 103f. However, the lid 103 is openable and closable with respect to the main body 102 by being fitted and inserted into cylindrical protrusions formed on both side plates including the first side plate 102 b of the main body 102.

An extra-length storage tray 104, an electronic circuit unit, and a power supply unit are built in a casing including the main body 102 and the lid 103.
The extra-length storage tray 104 shown in FIGS. 18 and 19 has a rectangular box shape with an upper surface opened. The extra-length storage tray 104 is composed of four sheets of a first side wall 104b, a second side wall 104c, a third side wall 104d, and a fourth side wall 104e that stand up from each of the four side edges of the rectangular bottom surface part 104a. A wall portion is provided, thereby forming a box shape with an upper surface opened. Since the length of the optical fiber is laid out with a margin, an extra length portion is generally generated in the optical fiber introduced into the optical terminal device 100. The extra length storage tray 104 is provided to store the extra length portion of the optical fiber introduced into the optical terminal device 100. The extra length storage tray 104 has a plurality of optical fibers wound around and stored therein. The guide portion is formed so as to stand up from the bottom surface portion 104a in a wall shape.

  The optical fiber introduced into the extra length storage tray 104 from the introduction groove 145c formed in the second side wall 104c is sandwiched and held by the sandwiching portion 145 in which the introduction groove 145c is formed. The sandwiching portion 145 has a sandwiching groove 145e formed with a plurality of rows of protrusions facing each other and a sandwiching piece 145a that covers the sandwiching groove 145e. The sandwiching piece 145a is a hinge portion. 145d can be opened and closed on the clamping groove 145e, and a locking piece 145b is formed outside the clamping piece 145a. The locking piece 145b is formed in a V shape and has elasticity, and is inserted into the clamping groove 145e when the clamping piece 145a is bent at the hinge portion 145d and placed on the clamping groove 145e. The optical fiber is clamped so as not to come out of the clamping part 145. At this time, the locking piece 145b is elastically locked in the locking hole 145f, and the sandwiching piece 145a is maintained in a closed state.

  An optical connector is provided at the tip of the optical fiber introduced into the extra length storage tray 104, and this optical connector is attached to the optical connector in the electronic circuit unit. At this time, the extra length of the optical fiber is wound and accommodated in a guide portion that is formed in a wall shape from the bottom surface portion 104a. In this guide portion, the first guide portion 141a is formed at the back of the bottom surface portion 104a, the second guide portion 141b is formed adjacent to the front side of the first guide portion 141a, and is adjacent to the front side of the second guide portion 141b. A third guide portion 141c is formed, and a fourth guide portion 141d is formed adjacent to the front side of the third guide portion 141c.

  Outer guide portions 146a to 146d each having an arc shape or an arc and a straight line are formed outside the first guide portion 141a to the fourth guide portion 141d. Between the guides of the first guide portion 141a to the fourth guide portion 141d and the outer guide portions 146a to 146d, a curved or linear groove having a substantially constant width is formed, and an extra length portion of the optical fiber is formed in the groove. Is wound or stored. A plurality of pressing claws are formed at predetermined intervals on the upper edge and intermediate position of each guide portion. The presser claw formed on the guide part includes an upper presser claw 142a formed on the upper edge of the guide part, and a lower presser claw shown with hatching formed at a height approximately in the middle of the guide part. 42b. This is because when the extra length portion of the optical fiber introduced into the optical terminal device 100 is wound and stored in the groove, the optical fiber has elasticity, and is biased in the direction in which the winding diameter increases. This is because the optical fiber may get messed up over the first guide portion 141a to the fourth guide portion 141d and the outer guide portions 146a to 146d, and the optical fiber gets over by the upper presser pawl 142a and the lower presser pawl 142b. It is prevented.

  Incidentally, there are cases where optical fibers are connected to each other in the housing of the optical terminal device 100. The optical fibers are connected to each other by fusing the end faces of the optical fibers, and a sleeve that protects the fused portion is attached to the fused portion. In addition, optical fibers are also connected by a mechanical splice that aligns and fixes the end faces of the optical fibers. Such sleeves and mechanical splices are stored in the casing of the extra length storage tray 104 together with the extra length of the optical fiber. Then, since the sleeve and mechanical splice are thicker than the optical fiber and are heavier than the optical fiber and cannot be bent, the optical fiber may be bent and damaged when it is moved so that it does not move in the housing. Occurs. Therefore, in the conventional optical terminal device 100, sleeve holding portions 143 and 144 for holding sleeves and mechanical splices are provided on both sides of the center of the extra length storage tray 104. The sleeve holding portions 143 and 144 that hold the sleeve and the mechanical splice have holding pieces, and elastically hold the sleeve and the mechanical splice between the outer guide portion 146e or the third side wall 104d and the holding piece. .

JP, 2015-121717, A

  In the conventional optical terminal device 100, the extra length portion of the optical fiber can be stored in the extra length storage tray. The extra length of the optical fiber is stored in a groove formed between the guides of the extra length storage tray. However, there is a case where it is desired to take out the extra length of the already stored optical fiber for some reason. However, the conventional optical terminal device has a problem in that it cannot be easily taken out because it is not configured to take out the extra length of the optical fiber.

  Accordingly, an object of the present invention is to provide an optical terminal device including an extra-length storage tray from which an optical fiber already stored can be easily taken out.

  An optical terminal device according to the present invention is an optical terminal device that converts an optical signal transmitted by an optical fiber into an electrical signal and outputs the electrical signal, and includes an extra-length storage tray that accommodates an extra-length portion of the optical fiber introduced therein. A plurality of guide portions that can be accommodated by winding the surplus length portion of the optical fiber, the at least one extra length storage tray being formed upright from a bottom surface portion of the surplus length storage tray; A plurality of elastic pressing claws extending radially from an upper edge of the predetermined guide portion of the plurality of guide portions, and in a normal state, the tip of the elastic pressing claw It protrudes in the groove | channel formed between these guide parts, and when the said elastic presser claw is bent, it does not protrude in the said groove | channel.

  The optical terminal device of the present invention includes a plurality of guide portions that can be accommodated by winding the extra length portion of the optical fiber, and extends radially from an upper edge of a predetermined guide portion of the plurality of guide portions. In the normal state, the tip of the elastic presser claw protrudes into a groove formed between the plurality of guide parts, and the elastic presser claw is bent. When projecting, it does not protrude into the groove. Thereby, when the elastic pressing claw is bent, the optical fiber can be easily taken out from the groove between the guide portions without being disturbed by the elastic pressing claw.

It is a perspective view which shows the structure of the optical terminal device concerning the Example of this invention. It is a perspective view which shows a structure when a cover part is opened in the optical terminal device concerning the Example of this invention. It is a top view which shows a structure when a cover part is opened in the optical terminal device concerning the Example of this invention. It is a perspective view which shows a structure when the sleeve holding part is opened in the extra length storage tray of the optical terminal device concerning this invention. It is a top view which shows a structure when the sleeve holding part is opened in the extra length storage tray of the optical terminal device concerning this invention. FIG. 6 is another perspective view showing a configuration when the sleeve holding portion is opened in the extra length storage tray of the optical terminal device according to the present invention, and a perspective view showing a configuration around the sleeve holding portion. It is a perspective view which shows the structure of the extra length storage tray of the optical terminal device concerning this invention. It is a top view which shows the structure of the extra length storage tray of the optical terminal device concerning this invention. It is AA sectional drawing which shows the structure of the extra length storage tray of the optical terminal device concerning this invention. It is another perspective view which shows the structure of the extra length storage tray of the optical terminal device concerning this invention. It is a top view which shows the structure of the state which bent the elastic press nail | claw in the extra length storage tray of the optical terminal device concerning this invention. It is BB sectional drawing which shows the structure of the state which bent the elastic pressing nail | claw in the extra length storage tray of the optical terminal device concerning this invention. It is a perspective view which shows a structure when a cover part is opened in the optical terminal device concerning the Example of this invention, and the sleeve holding part is opened in the extra length storage tray. It is a top view which shows a structure when the cover part is opened in the optical terminal device concerning the Example of this invention, and the sleeve holding part is opened in the extra length storage tray. It is a perspective view which shows the structure of the state which opened the cover part in the optical terminal device concerning the Example of this invention, and bent the elastic pressing nail | claw in the surplus length storage tray. It is a top view which shows the structure of the state which opened the cover part in the optical terminal device concerning the Example of this invention, and bent the elastic pressing nail | claw in the surplus length storage tray. In the conventional optical terminal device, it is a perspective view which shows a structure when a cover part is opened. It is a perspective view which shows the structure of the extra length storage tray of the conventional optical terminal device. It is a top view which shows the structure of the extra length storage tray of the conventional optical terminal device.

The configuration of an optical terminal device according to an embodiment of the present invention is shown in FIGS. 1 is a perspective view showing the configuration of the optical terminal device 1 according to the present invention, and FIG. 2 is a perspective view showing the configuration of the optical terminal device 1 according to the present invention when the lid 3 is opened. These are top views which show the structure of the optical terminal device 1 concerning this invention when the cover part 3 is opened.
As shown in these drawings, the optical terminal device 1 includes a housing that includes a main body 2 and a lid 3 that is pivotally supported by the main body 2 so as to be opened and closed. The main body 2 is formed by resin molding and has a rectangular box shape with an upper surface opened. The main body 2 is provided with two side plates, a front plate, and a rear plate that stand substantially perpendicularly from each of the four edges of the bottom surface, thereby forming a box shape. 1 to 3, a front plate 2a, a first side plate 2b, and a second side plate 2d among the four plates are shown. The height of the front plate 2a is formed higher than the height of the other three plates including the first side plate 2b and the second side plate 2d. Three protruding cylindrical portions 2e are formed in the lower half of the front plate 2a, and a coaxial terminal 51 is inserted through the cylindrical portion 2e to protrude. On both sides of the upper half of the front plate 2a, two optical fiber introduction holes 2f, which are vertical grooves having a narrow width, are formed on the left side and one on the right side, and a pair of optical fiber introduction holes 2f is formed between the left and right optical fiber introduction holes 2f. An engaging protrusion 2c is formed. The engaging protrusion 2c is a flat protrusion having a horizontally long cross section, and a downward slope is formed at the tip. A power cable 61 is led out from the left side of the front plate 2a, and a cable insertion port through which the power cable 61 is led out is provided on the left side of the front plate 2a. When this cable insertion port is not used, the cable insertion port has a waterproof structure by closing the slide piece with a slide piece. Furthermore, it is formed so that the attachment piece 2g protrudes from the left and right sides of the lower end of the front plate 2a. By inserting a screw through the insertion hole formed in the attachment piece 2g and screwing it to the wall of the building, The optical terminal device 1 can be installed on the wall of a building.

  The lid 3 is formed by resin molding and includes a rectangular upper surface plate 3a, and a first side surface plate 3b and a second side surface plate 3c which are formed upright from both sides of the upper surface plate 3a. An extending portion 3d extending forward is formed from the front side of the upper surface plate 3a, and a pair of engaging pieces 3e are formed at substantially right angles at the tip of the extending portion 3d. A wedge-shaped protrusion is formed inside the tip of the engagement piece 3e. Also, a substantially rectangular holding piece 3f extending downward from the rear part of the lower edge of the first side face plate 3b and the second side face plate 3c is formed, and a circular hole is formed in the holding piece 3f. The first side surface plate 2b and the second side surface plate 2d of the main body 2 are formed with pivots that are protrusions having a circular cross section at positions corresponding to the circular holes formed in the holding piece 3f in the lid portion 3. By inserting a circular hole formed in the holding piece 3f into the pivot, the lid 3 can be rotated with respect to the main body 2 so as to be opened and closed. When the lid 3 is closed to the main body 2, the pair of engaging pieces 3e are engaged with the pair of engaging protrusions 2c, respectively. Further, in the state in which the lid 3 is closed to the main body 2, when an upward force is applied by applying a finger to the extending portion 3 d, the engagement of the engagement piece 3 e is released from the engagement protrusion 2 c and the lid 3. Will open, and the state shown in FIG. 2 can be obtained.

  The casing made up of the main body 2 and the lid 3 incorporates an extra-length storage tray 4, an electronic circuit unit, and a power supply unit. The plurality of coaxial terminals 51 are provided on the front surface of the electronic circuit unit, and a power cable 61 is led out from the power supply unit. The electronic circuit unit has an optical connector, and an optical connector provided at the tip of the optical fiber 71 introduced into the optical terminal device 1 is attached, whereby an optical signal is supplied to the electronic circuit unit. It becomes like this. In the electronic circuit unit, the input optical signal is converted into an electric signal and output from the coaxial terminal 51. The power supply unit supplies power for operation to the electronic circuit unit.

A surplus length storage tray 4 is stored so as to overlap the electronic circuit unit and the power supply unit stored in the main body 2. The configuration of the extra length storage tray 4 is shown in FIGS. 4 to 6A and 6B. 4 is a perspective view showing the configuration when the sleeve holding portion is opened in the extra-length storage tray 4 as a viewpoint on the upper left side of the front surface, and FIG. 5 is the configuration when the sleeve holding portion is opened in the extra-length storage tray 4. FIG. 6A is another perspective view showing the configuration when the sleeve holding portion is opened in the extra-length storage tray 4, and is another perspective view from the upper right side of the rear surface, and FIG. 4 is an enlarged perspective view showing only a configuration around a sleeve holding portion 43. FIG.
The surplus length storage tray 4 is formed by molding a flexible resin such as polypropylene, and has a rectangular box shape with an open top surface as shown in these drawings. The extra-length storage tray 4 is composed of four sheets of a first side wall 4b, a second side wall 4c, a third side wall 4d, and a fourth side wall 4e that stand up at right angles from each of the four side edges of the rectangular bottom plate part 4a. A wall portion is provided, thereby forming a box shape with an upper surface opened. The extra length storage tray 4 is provided to store the extra length portion of the optical fiber 71 introduced into the optical terminal device 1 according to the present invention, and the optical fiber 71 is wound around the extra length storage tray 4. A plurality of guide portions for storage are formed in a wall shape from the bottom plate portion 4a.

  On both sides of the second side wall 4c, which is the front surface of the extra length storage tray 4, there are formed two introduction holes 45a formed as narrow vertical grooves into which the optical fiber 71 is introduced on the left side and one on the right side. The introduction hole 45a overlaps the optical fiber introduction hole 2f formed in the front plate 2a of the optical terminal device 1, and the optical fiber 71 introduced into the optical terminal device 1 from the optical fiber introduction hole 2f passes through the introduction hole 45a. Thus, it is introduced into the extra length storage tray 4. The introduced optical fiber 71 is sandwiched and held by the sandwiching portion 45 formed after the introduction hole 45a. Since the structure of the clamping part 45 is the same as that of the clamping part 145 in the conventional optical terminal device 100 shown in FIGS. 17 to 19, the description thereof is omitted.

  An optical connector (not shown) is provided at the tip of the optical fiber 71 introduced into the extra-length storage tray 4, and this optical connector is attached to the optical connector in the electronic circuit unit. The extra length portion of the optical fiber 71 at this time is wound and accommodated in a guide portion that is formed in a wall shape from the bottom plate portion 4a. In this guide portion, a first guide portion 41a having a crescent-shaped cross-sectional shape in which one surface is convex and the other surface is concave is formed on the rear side of the bottom plate portion 4a. Adjacent to the front side, a second guide portion 41b having an elliptical cross section with both surfaces convex is formed. Further, a third guide portion 41c having an elliptical cross section similar to the second guide portion 41b is formed adjacent to the front side of the second guide portion 41b, and adjacent to the front side of the third guide portion 41c. A fourth guide portion 41d having a crescent-shaped cross-section that is inverted upside down in the same shape as the one guide portion 41a is formed. Furthermore, a fifth guide portion 47 and a sixth guide portion 48 having a triangular cross section are formed between both sides of the second guide portion 41b and the third guide portion 41c facing each other.

The first guide portion 41a to the fourth guide portion 41d are formed side by side so that the central axes overlap from the back of the bottom plate portion 4a, and the convex shape of the second guide portion 41b is formed in the concave portion of the first guide portion 41a. Since the convex and concave curvatures are substantially equal to each other, an arc-shaped groove having a predetermined width is formed between them. In addition, the concave curved surface portion of the fourth guide portion 41d faces the convex curved surface portion of the third guide portion 41c, and the convex and concave curvatures are substantially equal. A circular groove having a predetermined width is formed. Further, an arcuate guide part 46a and an arcuate guide part 46b are formed on the outer side of the convex part of the first guide part 41a so that the curvature of the convex part and the arcuate guide parts 46a and 46b is substantially equal. Therefore, an arc-shaped groove having a predetermined width is formed between the two. The arc-shaped guide part 46a has an arc shape at both ends and a straight line at the center, an arc shape at one end faces the first guide part 41a, and an arc shape at the other end faces the fourth guide part 41d. ing. Further, an arcuate guide part 46a is formed to face from the left side of the third guide part 41c to the outside of the convex curved part of the fourth guide part 41d. The convex part and the arcuate guide part 46a Since the curvature is substantially equal, an arc-shaped groove having a predetermined width is formed between the two. In addition, the arc-shaped guide part 46b is formed inside the corner | angular part of the 4th side wall 4e, the 1st side wall 4b, and the 3rd side wall 4d. Further, an arcuate guide part 46d is formed on the arcuate outer side of one end of the arcuate guide part 46a.
Further, a groove having a predetermined width is also formed between the second guide portion 41 b and the third guide portion 41 c and the fifth guide portion 47 and the sixth guide portion 48.

The extra length of the optical fiber 71 introduced into the optical terminal device 1 is wound and accommodated in the groove having the predetermined width described above. However, since the optical fiber 71 has elasticity, it is wound when wound. It is biased in the direction that the diameter increases. As described above, when the optical fiber 71 is biased in the direction in which the winding diameter increases, the optical fiber may get over the first guide portion 41a to the sixth guide portion 48 and the arcuate guide portions 46a to 46d, and the maintenance becomes difficult. The workability such as the above may deteriorate, the appearance may deteriorate, and in the worst case, the transmission characteristics may be deteriorated. In order to prevent this, a plurality of pressing claws 42b are formed at predetermined intervals on the upper edges of the respective guide portions so as to protrude in the shape of a peak with a rounded tip. The holding claws 42b formed on the guide portion are also formed at predetermined positions on the first side wall 4b to the fourth side wall 4e. The length of the presser claw 42b is formed according to the width of the groove at the position to be formed.
As described above, since the first guide portion 41a to the sixth guide portion 48, the arcuate guide portions 46a to 46d, and the presser claws 42b are provided on the first side wall 4b to the fourth side wall 4e, they are introduced into the optical terminal device 1. The extra length of the optical fiber 71 can be accommodated between the holding claw 42b and the bottom plate portion 4a, and the optical fiber 71 can be prevented from jumping out as much as possible.

  As shown in FIG. 4 to FIG. 6A, the first guide portion 41a to the sixth guide portion 48 and the arcuate guide portions 46a to 46d are formed on the extra-length storage tray 4 so that the two do not intersect each other. A cylindrical winding portion and a cylindrical winding portion that intersects the two winding portions are configured. Thereby, the optical fiber 71 can be wound and accommodated in two winding parts. For example, when there are two signal systems such as a video system and a communication system before and after the connection portion of the optical fiber 71, the signal systems can be stored separately. If the extra length of the optical fiber 71 is not long, it may be wound and stored without being divided. In this manner, the optical fiber 71 can be wound and stored in a manner corresponding to the length of the extra length portion. In addition, the winding direction can be changed by winding the optical fiber 71 in the shape of figure 8.

  By the way, there are cases where a sleeve, which is a connection portion between optical fibers, or a cylindrical connection portion, which is a mechanical splice, is stored in the excess length storage tray 4 together with the excess length portion of the optical fiber 71. The sleeve is shown as a sleeve 72 in FIGS. 2 and 3, and is attached to the fused portion so as to protect the fused portion when the optical fibers are connected by fusing the end faces of the optical fibers. . The mechanical splice connects the optical fibers by aligning and fixing the end faces of the optical fibers. Such a cylindrical connection portion, which is a sleeve or a mechanical splice, is stored in the extra-length storage tray 4 together with the extra length of the optical fiber. The cylindrical connection portion has an elongated cylindrical shape whose diameter is larger than that of the optical fiber 71. Because it is heavier than the optical fiber 71 and cannot be bent, the optical fiber 71 will be bent and damaged when it is moved so that it will not move, or it will jump out of the extra length storage tray 4 It becomes like this. For this reason, it is held so as not to move in the extra length storage tray 4. In the optical terminal device 1 according to the present invention, a sleeve holding portion 43 and a sleeve holding portion 44 for holding a cylindrical connecting portion that is a sleeve or a mechanical splice are provided. In the following description, the case where the cylindrical connecting portion is the sleeve 72 will be described.

The sleeve holding portion 43 is provided in communication with the upper edge of the substantially center of the third side wall 4d and can be opened and closed. As shown in FIGS. 4 to 6A, two sleeve holding portions 44 are formed facing each other with the arcuate guide portion 46a interposed therebetween.
The configuration around the sleeve holding portion 43 is enlarged and shown in FIG. As shown in FIG. 6B, the sleeve holding portion 43 includes a flat plate-like main body portion 43a, and is connected to one edge of the main body portion 43a and the main body portion 43a to the upper edge of the substantially center of the third side wall 4d. A portion 43f is formed. The hinge portion 43f is formed with a small thickness, and the main body portion 43a is supported by the hinge portion 43f so as to be bendable with respect to the upper edge of the third side wall 4d. An elongated rectangular plate-like flat plate portion 43d is erected substantially at the center of the lower surface of the main body portion 43a so as to be substantially parallel to the third side wall 4d, and the holding piece 43e faces the flat plate portion 43d. It is formed upright from the tip of. Both sides of the holding piece 43e are formed obliquely so that the distance from the flat plate portion 43d is gradually reduced. When the sleeve 72 is inserted between the flat plate portion 43d and the holding piece 43e, the elasticity of the holding piece 43e is obtained. As a result, the sleeve 72 is elastically held and fixed. A V-shaped portion 43b is formed by extending from the center of the lower edge of the holding piece 43e, and an engaging piece 43c is formed at the tip of the V-shaped portion 43b so as to project at a substantially right angle. The sleeve holding portion 43 shown in FIGS. 4 to 6A and 6B is bent and opened. As will be described later, when the sleeve holding portion 43 is bent so as to be closed, the fifth guide portion 47 is provided. The engaging piece 43c of the sleeve holding portion 43 is engaged with a locking notch 47c on the upper edge of the opening 47a formed on the side facing the third side wall 4d.
Further, the sleeve holding portion 44 is formed so as to project in an L-shaped cross section from a height position substantially half of the arcuate guide portion 46a. A holding piece is formed on the sleeve holding portion 44 so as to face the arcuate guide portion 46a, and both sides of the holding piece are formed obliquely so that a distance from the arcuate guide portion 46a is gradually narrowed. When the sleeve 72 is inserted between the arcuate guide portion 46a and the holding piece, the sleeve 72 is elastically held and fixed by the elasticity of the holding portion.

Next, in the extra length storage tray 4 housed in the casing made up of the main body 2 and the lid 3 in FIG. 13, the sleeve holding portion 43 is opened and the optical fiber 71 introduced into the optical terminal device 1 is provided. The state of the preparatory work for holding the sleeve 72 is shown, and a top view showing the state is shown in FIG. The extra length portion of the optical fiber 71 introduced from the optical fiber introduction hole 2f and the introduction hole 45a is wound around the outer periphery of the first guide portion 41a and the fourth guide portion 41d in an elliptical shape. A sleeve 72 is provided in the extra length portion of the optical fiber 71, and the extra length portion is wound around the guide portion so that the sleeve 72 is positioned at the sleeve holding portion 43. In this extra length storage operation, the sleeve 72 is not fixed and can be moved, so that the sleeve 72 does not interfere with the extra length storage operation. When the extra length portion is stored, when the sleeve 72 is inserted between the flat plate portion 43d of the main body portion 43a and the holding piece 43e and the sleeve holding portion 43 is closed as shown in FIGS. The sleeve holding part 43 is fixed so as not to come out. When the sleeve holding portion 43 is closed, the engagement piece 43 c is engaged with the locking notch 47 c of the fifth guide portion 47. In this case, the width of the V-shaped portion 43b and the lateral width of the stepped portion 47b in the opening 47a are substantially the same, and the engaging piece 43c engaged with the locking notch 47c is easily formed by the elastic force of the V-shaped portion 43b. Will not be disengaged. The state where the sleeve holding portion 43 is closed in this way is shown in FIGS.
In the above description, the case where the sleeve 72 that protects the fused portion obtained by fusing the end faces of the optical fibers is held has been described, but the case where the mechanical splice for positioning and fixing the end faces of the optical fibers is also held, This can be performed in the same manner as the case where the sleeve 72 is held. In addition, the V-shaped portion 43b formed by extending from the center of the lower edge of the holding piece 43e is elastic because the cross-sectional shape is folded back to a V-shape. The V-shaped portion 43b may be a folded portion having elasticity.

Here, in an optical terminal device provided with a surplus length storage tray, there is a case where it is desired to take out the surplus portion of the already stored optical fiber for some reason. However, in the conventional optical terminal device 100, since it was not set as the structure considered taking out the extra length part of an optical fiber, it was not able to be taken out easily. In the extra length storage tray 4 according to the present invention, the extra length portion of the optical fiber can be easily taken out.
In the extra length storage tray 4 according to the present invention, four elastic pressing claws 49 are provided. The elastic pressing pawl 49 has a length that is considerably longer than the pressing pawl 42b. In the normal state, the tip protrudes from a wall portion of the guide portion into a groove formed between the guides, thereby preventing the optical fiber 71 from jumping out. . The elastic pressing claw 49 can be greatly bent, and when bent, the tip does not protrude into the groove between the guide portions. Thereby, when the elastic pressing claw 49 is bent, the extra length portion of the optical fiber 71 can be easily taken out from the groove between the guide portions without being obstructed by the elastic pressing claw 49. Hereinafter, this structure will be described with reference to FIGS.

7 is a perspective view showing the configuration of the extra length storage tray 4 as viewed from the upper left side of the front surface, FIG. 8 is a top view showing the configuration of the extra length storage tray 4, and FIG. FIG. 10 is a cross-sectional view taken along line AA showing the configuration of the extra length storage tray 4 cut by a line, FIG. 10 is a perspective view of the configuration of the extra length storage tray 4 as viewed from the upper right side of the rear surface, and FIG. FIG. 12 is a top view showing the configuration of the surplus length storage tray 4 in a state where the claw 49 is bent, and FIG. 12 is a BB cross-sectional view showing the configuration of the surplus length storage tray 4 cut along line BB in FIG. is there.
Since the configuration of the extra-length storage tray 4 shown in FIGS. 8 to 12 has already been described except for the elastic pressing claw 49, the elastic pressing claw 49 will be described.
As shown in FIGS. 8 to 12, a plurality of elastic pressing claws 49 are radially formed, and three elongated elastic pressing members are formed from the upper edge of the substantially central portion on the front side of the wall portion forming the first guide portion 41a. The claws 49 are formed so as to extend at intervals of about 90 ° from each other. That is, the elastic pressing claw 49 located at the center of the three is formed toward the fourth side wall 4e substantially parallel to the first side wall 4b and the third side wall 4d, and the remaining two elastic pressing claws 49 are the first side. It is formed so as to be aligned in a straight line toward the first side wall 4b or the third side wall 4d substantially parallel to the four side walls 4e. The fourth elastic pressing pawl 49 extends from the upper center of the rear center of the wall portion forming the second guide portion 41b toward the second side wall 4c substantially parallel to the first side wall 4b and the third side wall 4d. Is formed.

  Each elastic pressing claw 49 includes a base portion 49a, a long portion 49b, and a claw piece 49c. The base portion 49a extends from the upper edge of the guide portion so as to be substantially parallel to the bottom plate portion 4a, and extends from the base portion 49a. The elongated elongated portion 49b that is extended is formed slightly obliquely toward the bottom plate portion 4a, and the claw piece 49c at the distal end of the elongated portion 49b is formed obliquely upward, and the width increases toward the distal end. A wall having a predetermined height is formed around the periphery. As described above, the long portion 49b and the claw piece 49c are formed in a “shape” when viewed from the lateral direction. The long portion 49b is thinner than the base portion 49a so that it can be easily bent. When a downward force is applied to the elastic pressing claw 49, the claw piece 49c bends so as to come into contact with the bottom plate portion 4a as shown in FIGS. 11 and 12, and the claw piece 49c becomes a wall of the first guide portion 41a. It will not protrude from the part. Thereby, as described above, the extra length portion of the optical fiber 71 wound in the groove between the guides can be easily taken out by grasping with the finger. When the finger is released after the removal, the elastic pressing claw 49 returns to its original position due to its own elasticity. The bent elastic pressing claw 49 is represented as an elastic pressing claw 49 (F) in the drawing.

Next, in FIG. 15, in the extra length storage tray 4 stored in the casing made up of the main body 2 and the lid 3, the elastic pressing claw 49 (F) is bent, and this state FIG. 16 is a top view showing the above. As shown in these drawings, the extra length portion of the optical fiber 71 introduced from the optical fiber introduction hole 2f through the introduction hole 45a is wound around the outer circumference of the first guide portion 41a and the fourth guide portion 41d in an elliptical shape. It has been turned. The tip of the claw piece 49c of the elastic pressing claw 49 in the normal state is designed to prevent the optical fiber 71 from protruding beyond the optical fiber 71 as shown in FIG. 14, but the elastic pressing claw 49 (F ) Is bent, the tip of the claw piece 49 c is positioned inside the optical fiber 71. For this reason, the extra length portion of the optical fiber 71 can be easily grasped with a finger and taken out without being obstructed by the elastic pressing claw 49. In this case, if the bending force is loosened and the claw piece 49c is gradually raised, the tip of the claw piece 49c gradually protrudes from the wall portion of the guide portion, and the tip of the claw piece 49c becomes the optical fiber 71. It comes into contact with the lower side of the. This is because the long portion 49b and the claw piece 49c are formed in a "<" shape, so that when the elastic pressing claw 49 is bent, the lower surface of the claw piece 49c is substantially parallel to the bottom plate portion 4a. This is because the tip of the claw piece 49c comes to be positioned below the optical fiber 71. Then, as the claw piece 49c rises, the optical fiber 71 in contact with the claw piece 49c rises in the groove together with the claw piece 49c. As described above, depending on the storage position of the optical fiber 71 in the groove, the elastic pressing pawl 49 is bent and then gradually bent to be able to be taken out of the groove between the guide portions. Become.
Note that the number of elastic pressing claws 49 is not limited to four, and four or less or four or more may be formed radially.

The optical terminal device according to the present invention is limited to a device that demodulates and demodulates an optical signal transmitted through an optical fiber, and converts the demodulated electrical signal to a set-top box or a coaxial transmission line. Rather, it includes all electronic devices into which optical fibers are introduced.
In the optical terminal device according to the present invention described above, a plurality of optical fibers may be introduced into the optical terminal device from a plurality of optical fiber introduction holes provided on the left and right. In this case, the extra length portion of the optical fiber introduced into the optical terminal device may be stored by the extra length storage tray, and the optical fiber may be led out from the other optical fiber introduction hole. That is, the optical terminal device can also be used as extra length storage means for storing the extra length of the optical fiber.
Further, the elasticity of the holding piece of the sleeve holding portion and the elastic pressing claw in the extra length storage tray according to the optical terminal device of the present invention described above is based on the property of the synthetic resin forming the extra length storage tray. Yes. For this reason, a resin material that is somewhat flexible is used to create the extra-length storage tray. For example, a synthetic resin such as polypropylene is used. In this case, it is preferable to reduce the thickness of a portion where elasticity is desired and to increase the thickness of a portion where rigidity is desired.
Furthermore, the front plate of the main body according to the optical terminal device of the present invention described above is provided with a coaxial terminal, an optical fiber introduction hole, and a cable insertion hole through which the power cable of the power supply unit is drawn. In particular, the introduction and extraction of optical fiber lines and cables are concentrated. However, the present invention is not limited thereto, and a coaxial terminal, an optical fiber introduction hole, and a cable insertion hole through which a power cable is drawn out may be provided on the rear plate or side plate of the main body.

DESCRIPTION OF SYMBOLS 1 Optical terminal device, 2 Main-body part, 2a Front plate, 2b 1st side plate, 2c Engagement protrusion, 2d 2nd side plate, 2e Cylindrical part, 2f Optical fiber introduction hole, 2g Mounting piece, 3 Cover part, 3a Top plate, 3b first side plate, 3c second side plate, 3d extending portion, 3e engaging piece, 3f holding piece, 4 extra length storage tray, 4a bottom plate portion, 4b first side wall, 4c second side wall, 4d first 3 side wall, 4e 4th side wall, 41a 1st guide part, 41b 2nd guide part, 41c 3rd guide part, 41d 4th guide part, 42b holding claw, 43 sleeve holding part, 43a body part, 43b V-shaped part, 43c engagement piece, 43d flat plate part, 43e holding piece, 43f hinge part, 44 sleeve holding part, 45 clamping part, 45a introduction hole, 46a arcuate guide part, 46b arcuate guide part, 46d arcuate guide part 47 fifth guide portion, 47a opening, 47b stepped portion, 47c locking notch, 48 sixth guide portion, 49 elastic pressing claw, 49a base portion, 49b long portion, 49c claw piece, 51 coaxial terminal, 61 power cable, 71 optical fiber, 72 sleeve, 100 optical terminal device, 102 main body, 102a front plate, 102b side plate, 102c engaging projection, 102f optical fiber introduction hole, 103 lid, 103a top plate, 103b first side plate, 103c first 2 side plate, 103d extending portion, 103e engaging piece, 103f holding piece, 104 extra length storage tray, 104a bottom portion, 104b first side wall, 104c second side wall, 104d third side wall, 104e fourth side wall, 141a first Guide part, 141b Second guide part, 141c Third guide part, 141d Fourth guide , 142a Upper stage claw, 142b Lower stage claw, 143, 144 Sleeve holding part, 145 Clamping part, 145a Clamping piece, 145b Locking piece, 145c Introduction groove, 145d Hinge part, 145e Clamping groove, 145f Locking Hole, 146a to 146d Outer guide portion, 146e Outer guide portion, 151 Coaxial terminal, 161 Power cable

Claims (3)

An optical terminal device that converts an optical signal transmitted by an optical fiber into an electrical signal and outputs the electrical signal,
At least a surplus length storage tray for storing a surplus length portion of the optical fiber introduced therein;
The extra-length storage tray is
A plurality of guide portions that are formed upright from the bottom surface portion of the extra length storage tray and can be accommodated by winding the extra length portion of the optical fiber;
A plurality of elastic pressing claws extending radially from the upper edge of the predetermined guide portion of the plurality of guide portions;
In a normal state, the tip of the elastic pressing claw protrudes into a groove formed between the plurality of guide portions, and does not protrude into the groove when the elastic pressing claw is bent. An optical terminal device.   The elastic pressing claw includes a base portion extending from the upper edge of the guide portion, an elongated long portion extending from the base portion, and a claw piece protruding into the groove in a normal state, and the long portion 2. The optical terminal device according to claim 1, wherein the claw piece is formed in a "<" shape.   3. The optical terminal device according to claim 2, wherein the elastic holding claw is formed such that a thickness of the long portion is thinner than a thickness of the base portion, and the long portion is easily bent.

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