KR20120003858A - Optical fiber holder and fusion welding apparatus - Google Patents

Abstract

Provided is a holder and a fusion splicer including the holder capable of satisfactorily holding an optical cable without failure or damage. In the holder 21 which holds the terminal of the optical cable 11 which extended the optical fiber core 12 from the outer shell 16, the optical fiber core 12 and the outer part 16 of the optical cable 11 are The holder main body 22 which can be arranged, the core wire holding cover 31 which presses and holds the optical fiber core wire 12 arrange | positioned at the holder main body 22, and the part of the outer shell 16 arrange | positioned at the holder main body 22 Is provided with an outer covering lid 33 for pressing and holding at a pressing force stronger than that of the core wire holding lid 31.

Description

Optical fiber holder and fusion splicer {OPTICAL FIBER HOLDER AND FUSION WELDING APPARATUS}

The present invention relates to an optical fiber holder for holding an optical cable having an optical fiber core wire and a fusion splicer having the same.

When fusion-connecting optical fiber core wires of an optical cable, the holder holding the optical fiber core wire is mounted on a base having a thin groove for mounting the optical fiber core wire exposed to the end of the optical cable, and mounted on the thin groove of this base. There exists a cover which presses an optical fiber core wire (for example, refer patent document 1).

Japanese Patent Publication No. 2003-207679

By the way, the holder holds only the optical fiber core wires with weak tensile strength from the ends when fusion-bonding the optical fiber core wires, so that the optical fiber core wires are damaged or damaged during the welding operation, resulting in poor fusion connection between the optical fiber core wires. This may occur.

For example, in FTTH (Fiber To The Home) and the like, the optical fiber cord of the optical communication network is pulled through a repeater such as a plug to the home of the optical communication by the optical drop cable, but at the end of the optical drop cable If the fusion splicing work between the optical fiber core wires is defective, all of the optical drop cables must be fixed again, resulting in waste of the optical drop cable and unnecessary work.

SUMMARY OF THE INVENTION An object of the present invention is to provide an optical fiber holder and a fusion splicer having the same capable of holding an optical cable well without failure or damage.

The optical fiber holder of this invention which can solve the said subject is an optical fiber holder which hold | maintains the terminal of the optical cable which extended the optical fiber core wire from the outer skin, The holder main body which can arrange | position the optical fiber core wire and an outer skin part of the said optical cable, and And a core wire holding portion for pressing and holding the optical fiber core wire disposed on the holder body, and an outer shell holding portion for pressing and holding the sheath portion disposed on the holder body with a stronger pressing force than the core wire holding portion. It features.

Further, in the optical fiber holder of the present invention, the core wire retaining portion includes a magnet that presses the optical fiber core wire disposed on the holder main body by magnetic force, and the shell retaining portion retains the shell portion disposed on the holder main body. It is preferable to provide the biasing material pressurized by the biasing force.

Moreover, in the optical fiber holder of this invention, it is preferable that the said holder main body has a positioning surface which positions the said optical cable by the contact of the end surface of the said sheath.

Moreover, in the optical fiber holder of this invention, it is preferable to provide the intermediate holding part which presses and holds the outer skin part of the said optical cable between the said core wire holding part and the said outer skin holding part.

The fusion splicer of the present invention is a fusion splicer for fusion-splicing optical fiber core wires of an optical cable, and is characterized by comprising any one of the above optical fiber holders as an optical fiber holder for holding an end of the optical cable.

Moreover, in the fusion splicer of this invention, it is preferable that the said optical fiber holder is removable.

Furthermore, in the fusion splicer of the present invention, there is provided a heater for thermally shrinking a heat shrinkable tube covered by fusion spliced portions of optical fiber core wires, and holding the end of the optical cable to arrange the fusion spliced portion in the heater. It is preferable to provide some optical fiber holders mentioned above as a fiber holder.

According to the optical fiber holder of the present invention, since the core cable holding portion and the shell holding portion hold the optical cable not only in the optical fiber core wire but also in the shell portion, damage or damage of the optical fiber core wire by holding only the optical fiber core wire Without fail, the end of the optical cable can be held securely.

In addition, since the sheath holding portion firmly holds the outer skin portion by a pressing force stronger than the pressing force by the core wire holding portion, the holding force of the optical fiber core wire can be held well even if the holding force of the optical fiber core is weak, thereby suppressing the influence of the pressing force of the optical fiber core wire. can do. Thereby, even if there exists a some bending or twisting property in an outer part, it can hold | maintain favorably, correcting the property.

And since the fusion splicer of this invention is provided with the optical fiber holder which hold | maintains the edge part of an optical cable favorably and reliably, it can fusion-connect smoothly and satisfactorily between optical fiber core wires.

1 is a cross-sectional view of an optical cable made of an optical drop cable held by an optical fiber holder according to an embodiment of the present invention;
2 is a perspective view of an optical fiber holder according to the present embodiment;
3 is a perspective view of an optical fiber holder with each cover closed;
4 is a cross-sectional view of an optical fiber holder in an outer covering lid portion;
5 is a view for explaining the configuration of the optical fiber holder, (a) is a plan view, (b) is a side view seen from one end side, (c) a front view, (d) a side view seen from the other end side,
6 is a perspective view of a fusion splicer according to the present embodiment;
7 is a cross-sectional view illustrating a method of reinforcing a fusion spliced portion;
8 is a perspective view of a reinforcing part material provided at the fusion splicing part;
9 is a cross-sectional view illustrating a method of reinforcing a fusion spliced portion;
10 is a cross-sectional view illustrating a method of reinforcing a fusion spliced portion;
11 is a cross-sectional view illustrating a method of reinforcing a fusion spliced portion;
12 is a cross-sectional view illustrating a method of reinforcing a fusion spliced portion;
13 is a perspective view of a reinforcement material corresponding to the optical drop cable.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of the optical fiber holder and fusion splicer which concerns on this invention is described in detail with reference to drawings.

1 is a sectional view of an optical cable made of an optical drop cable held by an optical fiber holder according to the present embodiment, FIG. 2 is a perspective view of an optical fiber holder according to the present embodiment, and FIG. 3 is an optical fiber in a state where each cover is closed. The perspective view of a holder, FIG. 4 is sectional drawing of the optical fiber holder in a sheath holding cover part, FIG. 5 is a figure explaining the structure of an optical fiber holder, (a) is a top view, (b) is a side view seen from one end side, (c) is a front view, (d) is a side view seen from the other end side.

The optical fiber holder (henceforth a holder) of this embodiment hold | maintains the edge part of optical cables, such as an optical drop cable or an optical indoor cable. In this case, the optical drop cable will be described as an optical cable.

As shown in FIG. 1, the optical cable 11 which is an optical drop cable is provided in the longitudinal direction by the optical fiber core wire 12 covered by the protective coating 15, and the optical fiber core wire 12 in this direction. 11 d of cross-sectional rectangular cable parts which embedded the tension | tensile-strength body 11d in the outer shell 16 made from synthetic resin, and collectively coat | covered are provided. The support line part 11b which has the metal wire 18 is vertically attached to this cable part 11a.

The cable part 11a is connected between the cable part 11a and the support line part 11b via the thin part 11c, and is cut | disconnected so that the thin part 11c may be disconnected from the support line part 11b. I can do it. In addition, the optical fiber core wire 12 is embedded in the center part of the cross section of the cable part 11a, and the tensioning body 11d is embedded in the both sides. In addition, notches 11e are formed on the front and back of the cable portion 11a, and the optical fiber core wires 12 can be exposed by separating the cable portions 11a from these notches 11e. .

The holder 21 of this embodiment cuts the thin part 11c, isolate | separates from the support line part 11b, and hold | maintains the optical cable 11 which made only the cable part 11a.

Next, the holder 21 of this embodiment is demonstrated using FIGS.

The optical cable 11 held by this holder 21 comes out of the end part, and the optical fiber core wire 12 is exposed. In addition, the optical fiber core wire 12 has covered the glass fiber 13 with the coating | cover 14, the terminal process is provided, the coating | cover 14 is removed, and the glass fiber 13 is exposed.

In addition, the protective coating 15 covering the optical fiber core 12 is barely exposed from the outer shell 16.

The holder 21 holding the end of the optical cable 11 terminated in this way has a holder main body 22.

The holder main body 22 accommodates an outer sheathing groove 23 accommodating a portion of the outer sheath 16 of the optical cable 11 and an optical fiber core wire 12 drawn out from an end of the optical cable 11 on its upper surface. The core wire receiving groove 24 is formed.

The outer shell accommodating groove 23 is provided with a positioning surface 25 on the core wire accommodating groove 24 side, and the end face 16a of the outer shell 16 of the optical cable 11 accommodated in the outer accommodating groove 23 is The positioning surface 25 is in contact with it. Further, in the periphery of the positioning face 25, relief grooves; are formed (relief groove 26).

Moreover, between the outer shell accommodating groove 23 and the core wire accommodating groove 24, the protective coating accommodating groove 27 which accommodates the protective coating 15 barely exposed from the outer shell 16 is formed.

The holder main body 22 is provided with the core wire holding | maintenance cover (core wire holding | maintenance part) 31, the intermediate holding | maintenance cover (intermediate holding | maintenance part) 32, and the outer cover holding | covering (covering part) 33 in the one side part.

The core wire retaining cover 31 has a hinge portion 34, which is disposed in the retaining groove 35 formed in the holder main body 22. In addition, the intermediate holding lid 32 also has a hinge portion 36, and the hinge portion 36 is disposed in the holding groove 37 formed in the holder main body 22.

In addition, the holder main body 22 is provided with a connecting pin 38 penetrating through the holding grooves 35 and 37, and the connecting pin 38 is provided to a through insertion hole (not shown) formed in the hinge portions 34 and 36. It is inserted through. Thereby, the core wire retaining cover 31 and the intermediate retaining cover 32 are rotatably connected with respect to the holder main body 22 around the axis line of the connection pin 38, and these core retaining cover 31 And the surface of the holder main body 22 is opened and closed by rotating the intermediate holding lid 32. The core wire retaining cover 31 is disposed to cover the upper portion of the core wire accommodating groove 24 and the protective coating accommodating groove 27 by rotating toward the upper surface side of the holder main body 22. In addition, the intermediate holding lid 32 is disposed so as to cover the upper portion at one end side of the outer shell accommodating groove 23 by rotating toward the upper surface side of the holder main body 22.

The core wire retaining cover 31 and the intermediate retaining cover 32 are provided with pressing plate portions 41 and 42 made of an elastic material such as rubber, for example, on the opposite surface to the holder main body 22. 31) and the intermediate holding cover 32 are rotated toward the upper surface side of the holder main body 22, so that the pressing plate portion 41 is disposed above the core wire receiving groove 24, and the pressing plate 42 receives the outer shell. It is disposed above the groove 23.

In addition, the holder body 22 is provided with a magnet 44 on the upper surface on the side opposite to the one side to which the core wire retaining cover 31 and the intermediate retaining cover 32 are connected, and the core retaining cover 31 and the intermediate retaining cover When the core 32 is placed on the upper surface of the holder main body 22, these core wire holding lids 31 and the intermediate holding lid 32 come into contact with the magnet 44.

The core wire retaining cover 31 and the intermediate retaining cover 32 are formed from a magnetic material such as iron, whereby the core wire retaining cover 31 and the intermediate retaining cover 32 are formed on the surface of the holder main body 22. In the arranged state, it is attracted by the magnetic force of the magnet 44.

The outer cover lid 33 has a hinge portion 51, and the hinge portion 51 is disposed between the pair of support protrusions 52 formed in the holder main body 22. In the hinge portion 51 of the outer cover lid 33, a through insertion hole (not shown) is formed. In addition, a connecting pin 53 extends over the supporting protrusion 52 of the holder main body 22, and the connecting pin 53 is inserted through the through insertion hole of the hinge portion 51. Thereby, the outer cover holding cover 33 is rotatably connected with respect to the holder main body 22 centering on the axis line of the connection pin 53, and by rotating this skin holding cover 33, the holder The surface of the main body 22 is opened and closed. The outer cover lid 33 is disposed so as to cover the upper portion of the outer cover accommodating groove 23 by rotating toward the surface side of the holder main body 22.

The cable holding part 61 is provided in the outer cover lid 33. The cable pressing portion 61 is a pressing member 63 biased toward the holder main body 22 side by a compression spring (biasing member) 62 and a pressing plate portion mounted on the surface of the pressing member 63. Has 64. The press plate part 64 is formed with elastic materials, such as rubber | gum, for example, and the press plate part 64 accommodates an outer case by rotating the outer cover lid 33 toward the upper surface side of the holder main body 22. As shown in FIG. It is disposed above the groove 23.

The outer cover lid 33 has a fixing plate 71 on the side opposite to the connection side with the holder main body 22. This fixing plate 71 is arrange | positioned between the pair of support parts 72 formed in the outer cover holding cover 33, and is supported by the support pin 73 so that rotation is possible. The fixing plate 71 is formed with a claw portion 74 protruding to the connecting side of the holder main body 22 and the outer cover lid 33 on the rotational front side facing the holder main body 22. In this claw part 74, the surface on the front side in the rotational direction toward the holder main body 22 is a tapered surface 74a.

In addition, a compression spring 75 is provided between the fixing plate 71 and the outer cover lid 33 on the rear side in the rotational direction toward the holder main body 22 rather than the support pin 73. 75, the fixing plate 71 is biased in the direction of rotation toward the protruding direction of the claw part 74.

The holder main body 22 is provided with a fixing claw 77 which can fix the claw portion 74 of the fixing plate 71. This fixing claw 77 has the taper surface 77a which inclines downward gradually toward the protrusion direction.

The outer cover lid 33 is locked in the closed state with respect to the holder main body 22 by fixing the claw portion 74 of the fixing plate 71 to the fixing claw 77.

In this way, the holder 21 having the structure is attracted to the holder main body 22 by the magnetic force of the magnet 44 to hold the core wire holding the optical fiber core 12 and the outer skin 16 portions of the optical cable 11. The outer shell 16 of the optical cable 11 by the pressing force formed by the biasing force of the lid 31 and the intermediate retaining cover 32 and the compression spring 62 stronger than the core retaining cover 31 and the intermediate retaining cover 32. ) Is provided with an outer covering lid 33 for holding the portion.

In order to hold | maintain the optical cable 11 in the holder 21 of the said structure, first, the optical cable 11 is terminal-processed. Specifically, the outer sheath 16 is removed to expose the optical fiber core 12 covered with the protective coating 15, and the optical fiber core 12 is removed by leaving the protective coating 15 slightly. Expose Then, the coating 14 of the optical fiber core wire 12 is removed only for a predetermined length to expose the glass fiber 13.

Next, the holder main body 22 accommodates the optical cable 11 equipped with terminal processing in this way. Specifically, the outer shell 16 is accommodated in the outer shell accommodating groove 23 to accommodate the protective sheath 15 portion in the protective sheath accommodating groove 27, and the optical fiber core wire 12 is made into the core wire accommodating groove ( 24). At this time, the optical cable 11 is moved in the end direction, and the end surface 16a of the outer shell 16 contacts the positioning surface 25. In this way, the optical cable 11 equipped with the terminal processing is accommodated in a position positioned with respect to the holder main body 22.

Here, a burr etc. may be formed in the edge part of the end surface 16a of the outer shell 16 at the time of cutting | disconnection. However, when the end surface 16a of the outer shell 16 contacts the positioning surface 25, the burrs formed on the end surface 16a are drawn into the relief grooves 26 around the positioning surface 25. do. Therefore, the optical cable 11 can be accommodated in the holder main body 22, without being influenced by the burr formed in the end surface 16a of the outer shell 16. As shown in FIG.

When the optical cable 11 is accommodated in the holder main body 22, the core wire holding cover 31, the intermediate holding cover 32, and the outer cover holding cover 33 are rotated and closed respectively.

In this way, the core wire retaining cover 31 and the intermediate retaining cover 32 are adsorbed by the magnet 44 in a state arranged on the surface of the holder main body 22. Thereby, the optical fiber core wire 12 and the coating | cover 14 part are pressed and hold | maintained by the press plate 41 of the core wire holding cover 31, and the outer skin 16 part is hold | maintained of the intermediate holding cover 32, and is hold | maintained. It is pressurized and held by the press plate 42.

Moreover, in the outer cover holding cover 33, by rotating to the holder main body 22 side, the taper surface 74a of the claw part 74 of the fixing plate 71 is set as the fixed claw 77 of the holder main body 22. As shown in FIG. It contacts the taper surface 77a. When the sheath holding cover 33 is rotated in this state, the fixing plate 71 rotates in response to the biasing force of the compression spring 75. In addition, when the outer cover lid 33 is rotated, the claw portion 74 of the fixed plate 71 penetrates the fixed claw 77 and the fixed plate 71 rotates in the reverse direction by the biasing force of the compression spring 75. As a result, the claw portion 74 is fixed to the fixed claw 77, and the outer cover lid 33 is locked with respect to the holder main body 22.

At this time, the pressing plate portion 64 is pressed against the outer shell 16 portion of the optical cable 11 by the pressing member 63 biased toward the holder body 22 side by the compression spring 62. As a result, the outer shell 16 portion of the optical cable 11 is firmly held.

Thus, in the holder 21, the optical cable 11 is reliably held not only in the optical fiber core 12 part but also in the outer skin 16 part.

On the other hand, when removing the optical cable 11, the core wire holding cover 31, the intermediate holding cover 32, and the outer holding cover 33 are rotated in the opposite directions to open the upper surface of the holder main body 22, and the optical The holding of the cable 11 may be released.

In addition, the core wire retaining cover 31 and the intermediate retaining cover 32 are rotated in the reverse direction against the magnetic force of the magnet 44. In addition, the outer cover lid 33 rotates the fixing plate 71 against the biasing force of the compression spring 75, thereby releasing the fixing state of the claw portion 74 to the fixing claw 77 in the reverse direction. Rotate

Next, the fusion splicer will be described.

It is a perspective view seen obliquely upward of a fusion splicer.

As shown in FIG. 6, the fusion splicer 101 is an apparatus which fusion-splices the optical fiber core wires 12 of the optical cable 11 in the field where the construction of an optical fiber installation is performed, for example.

This fusion splicer 101 is provided with a fusion splicing part 104 provided with a pair of holder attaching parts 103 to which the holder 21 holding the end of the optical cable 11 is detachably mounted. And by attaching the holder 21 to the holder mounting part 103, the optical fiber core wire 12 of the optical cable 11 hold | maintained by each holder 21 is positioned in a fusion | melting position. In addition, holder 21 of symmetrical structure is attached to each holder mounting part 103. As shown in FIG.

The fusion processing unit 104 includes a pair of V-groove members 109 for positioning the tip position of the optical fiber core wire 12 extending from the holder 21 mounted to each holder mounting unit 103, and a pair of V grooves. It is arrange | positioned between the groove | channel member 109, and the electrode 113 which fuses the end surface of the glass fiber 13 of the opposing optical fiber core wires 12 with each other by discharge is provided.

In the fusion splicing unit 104, the optical fiber core wires 12 positioned at the fusion position are thermally fused at the glass fiber 13 portion to be connected.

The V-groove member 109 for positioning the optical fiber core 12 is dimensioned so as to support and position the optical fiber core 12 connected to each other in a straight line.

The holder attaching part 103 may attach the holder 21 in advance. In that case, the holder 21 attached to the holder attaching part 103 is hold | maintained the optical cable 11 equipped with the terminal process.

In addition, the fusion splicing part 104 is opened and closed by the opening / closing cover which is not shown in figure.

In addition, the fusion splicer 101 includes an adhesive tube (heat shrink tube) 134 and a protective tube (heat shrink tube) which will be described later on the outer circumference of the fusion spliced portion S (see FIG. 7) between the optical fiber core wires 12. The heat shrink processing part 116 which heat-shrinks 135 by a heater is provided. The heat shrink processing part 116 is provided with the exclusive opening / closing cover 118 and is provided adjacent to the fusion splicing part 104.

The heat shrink processing part 116 also has a holder mounting part 121 on which a holder 21 holding an end of the optical cable 11 is detachably mounted. And the holder 21 is attached to the holder mounting part 121, and the fusion splicing part S of the optical fiber core wires 12 is mutually positioned and arrange | positioned at the heat shrink processing part 116. FIG.

The heat shrink processing unit 116 is equipped with a heater (not shown) for heating and contracting the adhesive tube 134 and the protective tube 135. This heat shrink processing part 116 heat-shrinks the center part of the adhesion tube 134 and the protection tube 135 to high temperature, and provides the heating temperature distribution in a heater so that an edge part may shrink | contract after that. As a result, bubbles generated in the adhesive tube 134 and the protective tube 135 at the time of heating are easily released from both ends.

The fusion splicer 101 also includes an operation unit 119 for operating the fusion splicing part 104 and the heat shrink processing part 116.

Next, the case where the optical fiber core wires 12 of the optical cable 11 are fusion-spliced is demonstrated.

First, a terminal process is provided in each optical cable 11 connected to each other, and the optical fiber core wire 12 and the glass fiber 13 are exposed.

Next, the terminal portion of these optical cables 11 is held by the holder 21 (see FIGS. 2 and 3). At this time, the adhesive tube 134 and the protective tube 135 pass through the optical cable 11 in either direction.

When the optical cable 11 is held by the holder 21, the glass fiber 13 is cut into a predetermined length by a cutter to form an end surface, and each holder 21 is attached to the holder mounting portion 103 of the fusion splicer 101. (See Fig. 6).

In this way, the glass fiber 13 of the optical fiber core 12 extended from the holder 21 is positioned by the V-groove member 109 of the fusion splicing part 104, and the edge part of the glass fiber 13 Is abutted at the fusion position by the electrode 113.

In this state, the operation part 119 of the fusion splicer 101 is operated to discharge it to the electrode 113, and the end faces of the glass fibers 13 of the optical fiber core wire 12 are fusion-spliced.

When the optical fiber core wires 12 are fusion-spliced, the core wire holding cover 31, the intermediate holding cover 32, and the outer holding cover 33 of each holder 21 are opened to separate the optical cable 11.

Next, as shown in FIG. 7, the reinforcement part material 131 is poured into the fusion spliced part S of the optical cables 11 comrades.

Here, this reinforcement part material 131 is formed of metal, such as stainless steel, glass, or ceramics, for example, As shown in FIG. 8, the flat part 132 and the arc-shaped curved part (viewed from the cross section) 133). The flat part 132 of this reinforcement part material 131 recesses both end parts to the curved part 133 side with respect to the center part, and both end parts are lower than the center part. The central portion is a core wire arrangement region 132a in which the optical fiber core wire 12 portion is arranged, and the portion in which both end sides are recessed is an envelope arrangement region 132b in which the sheath 16 of the optical cable 11 is arranged. )

And the optical fiber core wire 12 part including a fusion splicing part S is arrange | positioned in the core wire arrangement area | region 132a of the planar part 132 of this reinforcement part material 131, and it coats in the envelope arrangement area | region 132b. (16) Place the part.

In this state, the adhesive tube 134 is slid to the fusion spliced portion S made by sliding the adhesive tube 134 made of the adhesive heat shrinkable resin so as to follow the reinforcing portion material 131 as shown in FIG. 9. Cover.

Here, the adhesive tube 134 has the length dimension L2 longer than the length dimension L1 of the part of the optical fiber core wire 12 containing the fusion splicing part S. As shown in FIG. Therefore, when the adhesive tube 134 is covered with the fusion spliced portion S along the reinforcement material 131, the adhesive tube 134 has both ends thereof at the outer skin 16 portion of each optical cable 11. Excreted over.

Thus, when the adhesive tube 134 is attached, the opening / closing cover 118 of the heat shrink processing part 116 is opened, and each optical cable 11 is held in each holder 21 of the heat shrink processing part 116. Let's do it.

In this way, the fusion spliced portion S of the optical fiber core wire 12 covering the adhesive tube 134 is positioned and disposed in the heat shrink processing portion 116.

In this state, the heater is generated by operating the operation unit 119 of the fusion splicer 101. By doing so, the adhesive tube 134 is sequentially thermally contracted at its center portion by the heater, and the adhesive tube 134 is in close contact with the fusion spliced portion S that follows the reinforcing portion material 131. Thereby, the fusion splicing part S of the optical fiber core wires 12 of the optical cable 11 is covered with the reinforcement part material 131, and is integrated by being covered by the adhesive tube 134 in close contact.

Next, as shown in FIG. 10, the optical cable 11 is separated from the holder 21, the protective tube 135 which consists of heat shrinkable resins is slid, and the fusion spliced part S covered by the adhesive tube 134 was carried out. ) Cover the protective tube (135).

Here, the protective tube 135 also has a length dimension L3 longer than the length dimension L1 of the part of the optical fiber core wire 12 including the fusion spliced portion S. As shown in FIG.

Therefore, when the protective tube 135 is covered with the fusion spliced portion S covered by the adhesive tube 134, both ends of the protective tube 135 are disposed on the outer shell 16 portion of each optical cable 11. .

In addition, the length dimension L2 of the adhesion tube 134 is longer than the length dimension L3 of the protection tube 135, and therefore the protection tube 135 is attached to the fusion spliced portion S covered by the adhesion tube 134. ), Both ends of the adhesive tube 134 protrude outward in the longitudinal direction from both ends of the protective tube 135. Further, the projecting dimension of both ends of the adhesive tube 134 at both ends of the protective tube 135 is preferably about 0.5 to 1.0 mm.

In this way, when the protective tube 135 is attached, the optical cable 11 is held in the holder 21 of the heat shrink processing unit 116.

In this way, the fusion spliced portion S of the optical fiber core wire 12 covering the protective tube 135 is positioned and disposed in the heat shrink processing portion 116.

In this state, the heater is generated by operating the operation unit 119 of the fusion splicer 101. In this case, the protective tube 135 is sequentially thermally contracted at the center portion by the heater, and the protective tube 135 is in close contact with the fusion spliced portion S covered by the adhesive tube 134. Thereby, as shown in FIG. 11, the fusion splicing part S of the optical fiber core wires 12 of the optical cable 11 comes with the reinforcement part material 131, and also the adhesive tube 134 which was in close contact. And is covered by the protective tube 135 and reinforced.

Here, the adhesive tube 134 and the protective tube 135 are heat-shrinked to the fusion spliced portion S, and the cover tube 16 is longitudinally covered with the outer cover 16 of the adhesive tube 134 and the protective tube 135. The dimension L4 becomes 7 mm or more.

That is, when the length dimensions L2 and L3 of the adhesive tube 134 and the protective tube 135 are heat-shrinked and brought into close contact with the fusion spliced portion S, the outer shells 16 of the respective optical cables 11 are provided. It is set in advance so as to cover 7 mm or more in the longitudinal direction.

When the fusion spliced portion S reinforced as described above is installed outdoors, the fusion spliced portion S is thermally shrunk with a weather resistant tube 136 as shown in FIG. 12 to protect the fusion spliced portion S. do. As the weatherproof tube 136, for example, a tube made of an electron beam crosslinked soft polyolefin resin is suitable, and thus the fusion spliced portion S can be better protected by the weatherproof tube 136.

In particular, the adhesive tube 134 and the protective tube 135 must be able to visually confirm the fusion splicing part S, and when it is formed from a transparent resin, the influence of an ultraviolet-ray can be suppressed.

In place of the weather resistant tube 136, a tape made of an electron beam crosslinked soft polyolefin resin may be wound around the fusion spliced portion S to heat shrink, and the fusion spliced portion S may be protected.

In addition, the fusion spliced portion S may be covered with a metal cylinder or the like, and by doing so, the fusion spliced portion S can be more firmly reinforced.

As described above, according to the holder 21 of the present embodiment, the optical cable 11 is not only the optical fiber core wire 12 but also the sheath 16 by the core wire retaining cover 31 and the outer cover retaining cover 33. Since only the optical fiber core wire 12 is held, the end portion of the optical cable 11 can be reliably held without failure such as breakage or damage of the optical fiber core wire 12.

In addition, since the sheath holding cover 33 firmly holds the portion of the sheath 16 by a pressing force stronger than the pressing force by the core wire holding cover 31, the holding force of the optical fiber core wire 12 is well held. The influence by the pressing force of the optical fiber core wire 12 can be suppressed. Thereby, even if the part of the outer shell 16 has a characteristic of some bending, distortion, etc., it can hold | maintain favorably, correcting the characteristic.

In addition, the core wire retaining cover 31 holds the optical fiber core wire 12 by the magnetic force of the magnet 44, and the outer cover retaining cover 33 is a part of the outer shell 16 by the biasing force of the compression spring 75. Since the pressing force with respect to the optical fiber core wire 12 which is weak to an external force is extremely small, the influence is small, and the part of the outer skin 16 which is strong against an external force can be reliably held by a large pressing force.

Moreover, since the positioning surface 25 which the end surface 16a of the outer shell 16 contacts is provided in the holder main body 22, it is made to contact the end surface 16a of the outer shell 16 with this main positioning surface 25. As shown in FIG. By doing so, the optical cable 11 can be easily positioned with respect to the holder main body 22.

Moreover, since the intermediate holding cover 32 which pressurizes and hold | maintains the part of the outer cover 16 of the optical cable 11 between the core wire holding cover 31 and the outer cover holding cover 33 was provided, the core wire holding cover 31 ) And the warping of the optical cable 11 in the intermediate portion of the outer cover holding lid 33 can be suppressed, and the optical cable 11 can be held more favorably.

And since the fusion splicer 101 which concerns on this embodiment is provided with the holder 21 which hold | maintains the edge part of the optical cable 11 favorably and reliably, the optical fiber core wires 12 mutually smoothly, The fusion splicing can be satisfactorily performed.

In particular, when the holder 21 is detachable, the holder 21 can be mounted on the fusion splicer 101 after holding the end of the optical cable 11 on the holder 21, thereby improving workability. .

Furthermore, since the holder 21 was also provided in the heat shrink processing part 116 provided with the heater which heat-shrinks the adhesive tube 134 and the protection tube 135 which were covered by the fusion splicing part S of the optical fiber core wires 12, The optical cable 11 can be held easily and reliably with respect to the heat shrink processing part 116, and the fusion spliced part S can be positioned in a heater. Thereby, workability in the heat shrink processing part 116 can also be improved.

In addition, in the said embodiment, although the optical drop cable of rectangular cross section was demonstrated as an example as the optical cable 11 to connect, the applicable optical cable 11 is not limited to an optical drop cable. For example, it is applicable also when connecting the optical fiber core wires 12 of the optical cable 11 which consists of an optical fiber cord of circular cross section.

As the reinforcement part material 131 used for the optical cable 11 which consists of a cross-section rectangular optical drop cable, as shown in FIG. 13, the optical cable 11 which consists of an optical drop cable in the outer skin | sieve arrangement area 132b. It is preferable to form the groove part 132c of the cross-sectional shape which conforms to the external shape of the outer part 16.

Thus, the groove part 132c which can accommodate the outer shell 16 part is formed in the outer shell arrange | position area | region 132b in which the outer shell 16 part in the reinforcement part material 131 is arrange | positioned, and the outer shell in the groove part 132c By disposing the portion (16), the mountability of the reinforcing portion material 131 to the outer shell 16 can be improved, and it can be integrated better.

In the fusion splicer 101, the holders 21 are detachable, but the holder 21 may be fixed to the fusion splicer 101.

In addition, the fusion splicer 101 includes a heat shrink processing unit 116 having a heater, and the heat shrink processing unit 116 heat shrinks the adhesive tube 134 and the protective tube 135, respectively. In addition, two heaters may be provided in the heat shrink processing unit 116 to heat shrink the adhesive tube 134 and the protective tube 135 in each heater.

Although this invention was detailed also demonstrated with reference to the specific embodiment, it is clear for those skilled in the art that various changes and correction can be added without deviating from the mind and range of this invention. This application is based on the JP Patent application (Japanese Patent Application No. 2009-058616) of an application on March 11, 2009, The content is taken in here as a reference.

11: optical cable 12: optical fiber core wire
16: sheath 16a: end face
21 holder (optical fiber holder) 22: holder body
25: positioning surface 31: core wire holding cover (core wire holding part)
32: middle holding cover (middle holding part) 33: outer covering holding cover (shell holding part)
44 magnet 62 compression spring (biasing member)
101: fusion splicer 134: adhesive tube (heat shrink tube)
135: protection tube (heat shrinkage tube) S: fusion splicing

Claims (7)

In the optical fiber holder which holds the terminal of the optical cable which extended the optical fiber core wire from the outer shell,
The core wire holding portion of the holder body in which the optical fiber core wire and the outer skin portion of the optical cable can be disposed, a core wire holding portion for pressing and holding the optical fiber core wire disposed on the holder body, and the shell portion disposed on the holder body. It is provided with the outer skin holding | maintenance part which pressurizes and hold | maintains by the pressure force stronger than a negative part, It is characterized by the above-mentioned.
Fiber optic holder. The method of claim 1,
The core wire holding portion includes a magnet that presses the optical fiber core wire disposed on the holder main body by magnetic force, and the shell retaining portion includes a biasing member that presses the outer skin portion disposed on the holder main body by a biasing force. Characterized by
Fiber optic holder. The method according to claim 1 or 2,
The holder main body has a positioning surface for positioning the optical cable by bringing the end surface of the sheath into contact with each other.
Fiber optic holder. The method according to any one of claims 1 to 3,
Between the core wire holding | maintenance part and the said outer skin holding | maintenance part, the intermediate holding | maintenance part which presses and holds the outer skin part of the said optical cable is provided, It is characterized by the above-mentioned.
Fiber optic holder. In the fusion splicer which fusion-splices optical fiber core wires of an optical cable,
The optical fiber holder according to any one of claims 1 to 4 is provided as a holder for holding an end of the optical cable.
Fusion splicer. In the fusion splicer according to claim 5,
The holder is detachable
Fusion splicer. In the fusion splicer according to claim 5 or 6,
The optical fiber holder which comprises the heater which heat-shrinks the heat shrink tube which hung on the fusion splicing part of optical fiber core wires, and arrange | positions the said fusion splicing part to the said heater, The optical fiber holder of Claims 1-4. It is provided with the optical fiber holder of any one of Claims characterized by the above-mentioned.
Fusion splicer.

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