JP4192750B2 - Optical fiber connecting member and optical fiber connecting method - Google Patents

Description

  The present invention relates to an optical fiber connecting member and an optical fiber connecting method capable of directly fixing an optical fiber cable.

Conventionally, there are three types of optical fiber connection technologies: fusion connection, connector connection, and mechanical splice connection. Among these, considering field construction when connecting optical fibers, there is an increasing demand for mechanical splices that do not require a commercial power source and can be assembled using simple tools.
As an optical fiber connector using a mechanical splice, an alignment mechanism that enables optical fibers to be brought into contact with each other is provided on the contact surfaces of the base and the lid, and the base and the lid are pressed by a C-type spring body. There was an optical fiber connector (see, for example, Patent Document 1 and Patent Document 2).

JP-A-9-61655 JP-A-9-96733

There are various types of optical fiber connectors that mechanically fix a 0.25 mm diameter optical fiber or a 0.9 mm diameter strand as in the prior art described above. It was.
However, an optical fiber connecting member using this type of mechanical splice cannot directly fix an optical fiber cable. For this reason, when connecting an optical fiber cable with a conventional optical fiber connecting member, after removing the tension member, the optical fiber core wire or the optical fiber strand is pulled out to some extent from the optical fiber cable, and the end is polished. It was necessary to perform connection processing after doing the same. Furthermore, after the connection, it was necessary to wind up and store the extra length of the optical fiber core wire or the optical fiber strand in another component (such as an optical fiber storage tray) and fix the optical fiber cable. .
For this reason, when using an optical fiber connecting member by a conventional mechanical splice, not only is the work of connecting the optical fiber troublesome, but also a skilled technique (skill), and further, an arrangement space for each component is required. In order to realize FTTH (Fiber to the home), the work of laying the optical fiber to each home was affected.

  Accordingly, the present invention has been made to solve the above problems, and an object of the present invention is to provide an optical fiber connecting member and an optical fiber connecting method capable of directly fixing an optical fiber cable and connecting an optical fiber with a simple operation. And

In order to solve the above-mentioned problems, the present invention provides an optical fiber connecting member having a fiber fixing portion that presses a glass portion of an optical fiber to position, support and mechanically fix the optical fiber, and is provided on both sides of the fiber fixing portion. outside have a cable fixing portion for fixing the and a fiber fixing unit having a fiber fixing portion, the cable fixing portion is disposed on both sides of the housing unit to pay the fiber fixing unit, the housing part and the cable fixing portion And a cable fixing unit in which each cable fixing part has a cable insertion hole communicating with the storage part, and the fiber fixing unit and the cable fixing unit are detachably configured. Is an optical fiber covering portion around the glass portion of the optical fiber between the fiber fixing portion and the cable fixing portion. The optical fiber connecting member having a coating fixing portion for positioning and fixing supporting pressed characterized.
In this optical fiber connecting member, an optical fiber cable is inserted from both sides of the fiber fixing portion, and the glass portion of the optical fiber is pressed, positioned, supported and mechanically fixed in the fiber fixing portion, and the optical fiber is maintained in this state. The jacket of the cable can be fixed by the cable fixing portion. Further, since the fiber fixing unit can be detached from the cable fixing unit, the fiber fixing unit can be retrofitted to the cable fixing unit, and the fiber fixing unit can be replaced with another fiber fixing unit. Furthermore, the fiber fixing unit can fix and fix the glass portion of the optical fiber while pressing and positioning the optical fiber coating portion around it.

And any of the above optical fiber connecting members is configured such that the cable fixing portion is arranged so as to oppose the fixing member having the demon portion, and the optical fiber cable can be gripped by the demon portion of the fixing member. it can. In addition, the cable fixing portion may be configured by opposingly arranging a fixing member having a bending portion corresponding to the optical fiber cable, and the optical fiber cable can be gripped by the bending portion of the fixing member.
In these cable fixing portions, an optical fiber cable can be sandwiched and fixed between the fixing members.

Also, the cable fixing portion can include a fixing member having a chuck structure that can be expanded, and the optical fiber cable can be clamped and held by an annular member or a screw member that can slide.
In the cable fixing portion, the optical fiber cable can be fixed by sandwiching the optical fiber cable between the fixing members and tightening the fixing member with an annular member or a screw member.

Also, the present invention provides a first and second optical fiber cables having an optical fiber to be connected by an optical fiber connecting member, each of which has a predetermined length after the outer sheath is removed and the optical fiber covering portion is removed. And the first and second optical fiber cables are inserted from the cable insertion holes formed in the cable fixing portion of the optical fiber connecting member, and the glass portions of the optical fibers in the first and second optical fiber cables are inserted. When the end face hits, the glass part of each optical fiber is pressed and positioned and supported by the fiber fixing part of the optical fiber connecting member, and the optical fiber coating part is pressed and positioned and supported by the coating fixing part. An optical fiber connection method is provided in which the outer sheaths of the first and second optical fiber cables are fixed by a cable fixing portion.
According to this connection method, the optical fiber connecting member is positioned and supported and fixed while pressing the glass portion of the optical fiber, and the optical fiber coating portion is pressed and positioned and supported and fixed. The jacket can be fixed.

  According to the present invention, in the optical fiber connecting member and the optical fiber connecting method, the optical fiber cable can be directly fixed and the optical fiber can be connected by a simple operation.

Embodiments of an optical fiber connection member and an optical fiber connection method according to the present invention will be described below in detail with reference to the accompanying drawings.
(Embodiment of optical fiber connecting member)
FIG. 1 is a perspective view showing an optical fiber connecting member 100 according to the present embodiment, and FIG. 2 is a cross-sectional view taken along the line II-II in FIG. As shown in FIGS. 1 and 2, an optical fiber connecting member 100 includes a fiber fixing unit 10 having a fiber fixing part for mechanically fixing an optical fiber, and a cable fixing unit 20 having a cable fixing part for fixing an optical fiber cable. And have.

  The fiber fixing unit 10 includes a sheet portion 1, a plate portion 2, a clamp member 3, and a gap adjusting member 4. The sheet portion 1 is a member having an appropriate length and width that can support the glass portion (cladding) and the covering portion of the optical fiber, and is made of, for example, aluminum. As shown in FIG. 4, the sheet portion 1 is a fiber fixing portion that mechanically fixes the glass portion of the optical fiber together with the plate portion 2, and after positioning and supporting the glass portion of the optical fiber as shown in FIG. For example, a V-groove 1a having an included angle of 60 ° is provided. In addition, the sheet part 1 is a coating fixing part for fixing the optical fiber coating part together with the plate part 2 on both sides of the V-groove 1a, for positioning and supporting the optical fiber coating part. It has a groove 1b. The V-groove 1a and the V-groove 1b are connected via an optical fiber tapered portion 8. The optical fiber taper portion 8 is a funnel-shaped inclined surface whose diameter gradually decreases from each V-groove 1b toward the V-groove 1a.

  The sheet portion 1 has a stepped groove 1c parallel to the V groove 1a and the V groove 1b. The groove 1c has an inclined surface 1f between the deepest portion 1d and the shelf portion 1e. The step between the deepest portion 1d and the shelf portion 1e in the groove ic is set between the sheet portion 1 and the plate portion 2 according to the required gap size. Locking portions 1g for preventing the gap adjusting member 4 from coming off are formed on both sides of the shelf portion 1e so as to determine the width of the deepest portion 1d.

  In addition, the sheet portion 1 only needs to have a groove formed as a fiber fixing portion and a covering fixing portion for positioning and supporting each of the optical fiber and the optical fiber covering portion, and the cross-sectional shape is as follows. It is not limited to the V-shaped V-groove 1b as shown in FIG. 8A (the same applies to the V-groove 1a). For example, it may be a semicircular groove 1h having a slightly larger size than each of the optical fiber and the optical fiber coating portion as shown in FIG. 8B, and the optical fiber and optical fiber coating as shown in FIG. A substantially U-shaped groove 1i having a size slightly larger than each of the portions may be used.

  The plate portion 2 is a plate-like member having a flat portion that presses the optical fiber and the optical fiber coating portion placed on the V-groove 1a and the V-groove 1b in the sheet portion 1, and is made of, for example, aluminum. . As shown in FIG. 11, the plate portion 2 is formed with a stepped groove 2 c due to a mirror image relationship with the groove 1 c. The groove 2c has an inclined surface 2f between the deepest portion 2d and the shelf 2e. The level difference between the deepest part 2d and the shelf 2e is set according to the required gap size. Locking portions (not shown) for preventing the gap adjusting member 4 from coming off are formed on both sides of the shelf portion 2e so as to determine the width of the deepest portion 2d. Although the illustrated plate portion 2 is integrally formed, a portion that presses the optical fiber corresponding to the V-groove 1a and a portion that presses the optical fiber coating portion corresponding to the V-groove 1b are separate members. It may be.

  The clamp member 3 is a member for pressurizing both the optical fiber and the optical fiber covering portion by the sheet portion 1 and the plate portion 2 and is made of steel and has a substantially U-shaped cross section. Has been. The clamp member 3 has a long beam structure with respect to the deformation amount so that there is no great difference in shape in two states obtained by moving the gap adjusting member 4 to a first position and a second position described later. It is set. As shown in FIG. 3, the clamp member 3 has strip-shaped guide protrusions 3a at both ends in the width direction so that the fiber fixing unit 10 and the cable fixing unit 20 can be attached and detached.

  The gap adjusting member 4 is a member that is disposed between the sheet portion 1 and the plate portion 2 and provides a predetermined gap therebetween. As shown in FIG. The plate portion 2 is formed in an elongated rectangular parallelepiped shape along the width direction. The gap adjusting member 4 includes a head portion 4a, a neck portion 4b, and an inclined portion 4c that connects the head portion 4a and the neck portion 4b. The gap adjusting member 4 has ears 4d extending on both sides of the head 4a, and a rectangular parallelepiped grip 4e is formed on the neck 4b.

  As shown in FIGS. 1 to 3, the cable fixing unit 20 has cable fixing portions 22 on both sides of the receiving portion 21, and has a back surface portion 23 on the back side of the receiving portion 21. In addition, the cable fixing unit 20 has a space corresponding to the outer dimensions of the fiber fixing unit 10 between the cable fixing portions 22, and the space serves as a storage portion 27 for housing the fiber fixing unit 10. The receiving portion 21 has a size capable of placing the fiber fixing unit 10 and is formed in a substantially rectangular shape having a size corresponding to the fiber fixing unit 10.

  Each cable fixing portion 22 is arranged on both sides of the receiving portion 21, and can hold and fix an optical fiber cable inserted from the outside. Each cable fixing portion 22 has a depth corresponding to the depth of the fiber fixing unit 10 and an appropriate width. Each cable fixing portion 22 has a cable insertion hole 22a communicating with the storage portion 27 from the outside, and a fixture 26 having a substantially prismatic fixing member 24 and a locking portion 25 sandwiches the center of the fiber insertion hole 22a. It arrange | positions so that it may mutually oppose (opposite arrangement | positioning). Each cable fixing portion 22 has an insertion hole 22b for inserting each fixing member 24, the guide projection 3a of the clamp member 3 in the fiber fixing unit 10 is fitted, and the fiber fixing unit 10 is received by the receiving portion 21. The guide groove 22c is slidable back and forth. By fitting the guide protrusion 3 a into the guide groove 22 c, the fiber fixing unit 10 slides along the receiving portion 21 and is detachable from the cable fixing unit 20.

  Each fixing member 24 is slidably provided along the insertion hole 22b. The fixing member 24 is made of a material having flexibility, and has a base portion 30, a demon portion 31, an arm portion 32, and a slit 33 as shown in FIG. The base 30 has a curved surface 30a along the housing body 21, and a demon portion 31, an arm portion 32, and a slit 33 are formed on the opposite side of the curved surface 30a. The demon portion 31 has a plurality (four in the figure) of strip-shaped protrusions 31a. Each protrusion 31a is arranged in parallel to the length direction, and the side surface on the arm portion 32 side is an inclined surface, and the opposite side surface is a substantially vertical standing surface. The arm portion 32 is formed with a locking claw 32 b protruding outward at the tip of a locking piece 32 a connected to the base 30. The slit 33 is provided between the demon portion 31 and the arm portion 32.

The locking part 25 protrudes toward the cable insertion hole 22a so as to face each other outside the fixing members 24. Each locking portion 25 has a protrusion 25 a that extends toward the inside of the housing body 21 at the tip.
Each cable fixing portion 22 may have a fixing member of another shape instead of the fixing member 24 having the demon portion 31 shown in FIG. For example, as shown in FIG. 7, a fixing member 42 having a curved portion 41 corresponding to the surface shape of the optical fiber cable may be provided instead of the demon portion 31.

On the other hand, in the above description, the optical fiber connecting member 100 has a substantially rectangular parallelepiped shape. However, as shown in FIGS. 9 and 10, the optical fiber connecting member in the present invention is a substantially cylindrical optical fiber connecting member. You can also. The optical fiber connecting member has a cable fixing unit 120 shown in FIG. 9 and a fiber fixing unit 110 shown in FIG.
The fiber fixing unit 110 includes a semi-cylindrical sheet portion 111 and a plate portion 112, and includes a clamp member 113 having a C-shaped cross section and a gap adjusting member 4. The sheet part 111 and the plate part 112 have the same configuration as the above-described sheet part 1 and the plate part 2 except that their shapes are different. The clamp member 113 is a member for pressurizing both the sheet portion 111 and the plate portion 112 so as to sandwich the sheet portion 111 and the plate portion 112, and has a protrusion 113a on an end face in the axial direction.

The cable fixing unit 120 has cable fixing portions 55 on both sides of a semi-cylindrical receiving portion 121. The cable fixing unit 120 has a space corresponding to the outer dimensions of the fiber fixing unit 110 between the cable fixing portions 55, and the space serves as a storage portion 127 for storing the fiber fixing unit 110. The guide hole 120a which faces is facing.
Each cable fixing portion 55 has an expandable chuck (collet chuck) structure, and includes a fixing member 53 that forms an insertion hole 55a communicating with the storage portion 127, and a slidable annular member 54, and is fixed. The optical fiber cable can be clamped and held by the member 53 and the annular member 54. In other words, the cable fixing portion 55 can fix the optical fiber cable inserted into the cable insertion hole 54a by maintaining the opening angle of the fixing member 53 by sliding the annular member 54 and covering the fixing member 53. it can. Although not shown, an annular member that can be tightened and released by a screw member is attached to the fixing member 53, and the optical fiber cable may be fixed by screwing the screw member in the annular member.

(Embodiment of optical fiber connection method)
Next, an optical fiber connection method using the optical fiber connection member 100 will be described with reference to FIGS. Prior to the optical fiber connection, the optical fiber connecting member 100 is in a state in which the fixing member 24 is not engaged with the locking portion 25 in each cable fixing portion 22 and is slidable along the insertion hole 20b.
Further, the fiber fixing unit 10 is attached to the cable fixing unit 20 by fitting the guide protrusion 3 a of the clamp member 3 into the guide groove 22 c in each cable fixing portion 22.

  In this state, first, with respect to the optical fiber cables 50 and 51 having the optical fiber to be connected by the optical fiber connecting member 100, a part of each outer sheath is removed and the optical fiber core wire is taken out. The coating is removed and then cut to a predetermined length to expose the optical fibers 50a and 51a. In addition, a refractive index matching agent (silicone oil) is previously injected onto the V groove 1a.

  Then, in the fiber fixing unit 10, the gripping portion 4 e of the gap adjusting member 4 is pinched by hand to move the gap adjusting member 4 from the first position to the second position. Here, as shown in FIG. 11A, the first position means that the portion other than the grip portion 4e in the gap adjusting member 4 is placed between the sheet 1 and the plate 2, and the sheet 1 and the plate 2 are This is the position when the contact is made so that no gap is formed between them. With this movement, as shown in FIGS. 11 (b) and 11 (c), the sheet 1 and the plate are moved by the wedge action between the inclined portion 4c of the gap adjusting member 4 and the inclined surfaces 1f and 2f of the sheet 1 and the plate 2. 2 and a gap is formed between the two, and the head 4a abuts on the shelves 1e and 2e in the grooves 1c and 2c (the head 4a prys between the shelves 1e and 2e), and the ears 4d moves to the second position where it comes into contact with the locking portion 1g. Then, a gap (for example, 0.05 to 0.1 mm) is formed between the sheet 1 and the plate 2 so that the optical fibers 50 and 51 can be inserted. In this state, the optical fiber cables 50 and 51 are inserted into the fiber insertion holes 22a from the outside of the cable fixing portions 22, respectively.

  Then, since each fixing member 24 is not engaged with the locking portion 25 and is slidable along the insertion hole 22b, the optical fiber cables 50 and 51 pass between the opposing fixing members 24, The covering portion (optical fiber covering portion) of the optical fiber core wire reaches the fiber fixing unit 10. Then, since the V-shaped groove 1b is formed in the fiber fixing unit 10, the respective optical fiber coating portions 50b and 51b enter inside thereof, but since the optical fiber taper portion 8 is formed, The optical fibers 50 a and 51 a and the optical fiber coating portions 50 b and 51 b proceed to the back while being guided by the optical fiber taper portion 8. Thus, since the optical fibers 50a and 51a are guided by the optical fiber taper portion 8, the optical fibers 50a and 51a can be inserted without damaging the end face.

  The optical fibers 50a and 51a abut each other at the end of the refractive index matching agent. At this time, when the optical fiber covering portions 50b and 51b come into contact with the optical fiber taper portion 8, the optical fiber covering portions 50b and 51b become dead ends there, and cannot travel deeper than that. Therefore, even if a force for further pushing the optical fiber covering portions 50b and 51b is applied after the optical fibers 50a and 51a are abutted, the optical fibers 50a and 51a are not pushed too much. 50a and 51a can be protected.

  In this state, the grip portion 4e of the gap adjusting member 4 is pinched by hand to move the gap adjusting member 4 from the second position to the first position. Then, as shown in FIG. 5D, the sheet 1 and the plate 2 are pressed by the elasticity of the clamp member 3, and a minimum gap formation state determined by the diameters of the optical fiber covering portions 50b and 51b is obtained. Thereby, as shown in FIG. 12, the optical fibers 50a and 51a are fixed by the sheet 1 and the plate 2, and the fixing of the optical fiber covering portions 50b and 51b is also completed. That is, since the optical fiber coating portions 50b and 51b are housed in the V groove 1b outside the V groove 1a, the optical fiber coating portions 50b and 51b are fixed together with the optical fibers 50a and 51a. Thereby, together with the connection of the optical fibers 50a and 51a, the optical fiber covering portions 50b and 51b are fixed, so that the mechanical strength in the connection state of the optical fibers 50a and 51a is increased, and the connection state is made stronger. The reliability of the connection state can be improved.

  Next, when the connection of the optical fibers 50a and 51a is completed, the four fixing members 24 in each cable fixing portion 22 are then pushed in along the insertion holes 22b. Then, since the fixing member 24 has flexibility, the locking claw 32b of the arm portion 32 gets over the projection 25a of the locking portion 25 and enters the inside, and the locking claw 32b and the projection 25a are engaged. Due to the engagement between the locking claws 32b and the protrusions 25a, the fixed member 24 can be maintained in a pressed state by preventing the fixed member 24 from moving while being pressed inward. Then, since the fixing member 24 has the demon part 31, each demon part 31 bites into the jacket of the optical fiber cables 50 and 51 as shown in FIG. Thereby, the optical fiber cables 50 and 51 are fixed to the optical fiber connecting member 100 so that they cannot be inserted and removed. That is, in the optical fiber connection member 100, the optical fiber cables 50 and 51 can be fixed so that they cannot be inserted and removed while the connection state of the optical fibers 50a and 51a is maintained.

  As described above, in the optical fiber connecting member 100, the optical fiber cables 50 and 51 to be connected are exposed to the optical fibers 50a and 51a, then inserted into the optical fiber connecting member 100, and the optical fiber. The optical fibers 50a and 51a can be connected only by fixing the optical fiber cables 50 and 51 in the fixing portion 22. Further, since the optical fiber connecting member 100 can not only connect the optical fibers 50a and 51a but also directly fix the optical fiber cables 50 and 51, the optical fiber connecting member 100 can be used to connect an optical fiber core or an optical fiber. It is not necessary to wind up and store the extra length of the fiber strand or the like in a separate part and fix the optical fiber cable to the separate part. Therefore, according to the above-described connection method using the optical fiber connection member 100, the optical fiber connection and the optical fiber cable fixing work are greatly simplified, and the procedure is simplified. Specially skilled techniques are not required to do so. In addition, since there is no need for a part for winding up the extra length such as an optical fiber core wire or an optical fiber strand, it is suitable without taking up extra space.

  On the other hand, it is assumed that the connection of the optical fibers 50a and 51a has failed for some reason during the above connection operation. In that case, the optical fiber cables 50 and 51 may be removed from the optical fiber connection member 100 and connected again. In this case, first, the arm portion 32 of each fixing member 24 is pushed in from both sides of the optical fiber connecting member 100 using a predetermined instrument. Then, since the fixing member 24 has flexibility and the slit 33 is formed, the arm portion 32 is pushed and bent toward the inside of the housing main body 21 by the amount of the slit 33, and the locking claw 32b and the protrusion The engagement with 25a can be released. Then, the fixing member 24 protrudes and slides while being pushed by the optical fiber cables 50 and 51, so that the fixed state of the optical fiber cables 50 and 51 is released and the optical fiber cables 50 and 51 can be inserted and removed.

Further, when the gap adjusting member 4 is moved from the first position to the second position to form a gap between the sheet 1 and the plate 2 in the fiber fixing unit 10, the optical fiber cables 50 and 51 are connected to the optical fiber connecting member. It can be extracted from 100 and removed. After that, a refractive index matching agent is injected into the V groove 1a, and thereafter, the connection of the optical fibers 50a and 51a and the fixing of the optical fiber cables 50 and 51 may be performed as described above.
Thus, the optical fiber connection member 100 failed to connect the optical fiber because the optical fiber fixing portion 22 for fixing the optical fiber cables 50 and 51 can release the fixed state of the optical fiber cables 50 and 51. However, it is possible to easily perform the redo.

The optical fiber connecting member 100 can also be used for connecting another optical fiber by connecting the optical fiber and then removing the optical fiber cable in the above-described procedure. That is, the optical fiber connection member 100 can be reused.
Furthermore, since the fiber fixing unit 10 and the cable fixing unit 20 are detachable from the optical fiber connecting member 100, the fiber fixing unit 10 can be detached from the cable fixing unit 20 as necessary. The fiber fixing unit 10 is different from the fiber fixing unit 10 in the structure of the fiber fixing unit that mechanically fixes the optical fiber. However, if the fiber fixing unit has a structure that can be accommodated in the storage unit 27 of the cable fixing unit 20, the cable fixing unit 20 Can be retrofitted. Then, it is possible not only to use the existing optical fiber connecting component for fixing the optical fiber core wire or the strand for the optical fiber core wire or the optical fiber strand, but also to be the optical fiber connecting component in the present embodiment. Become.

  On the other hand, when the optical fiber connecting member shown in FIGS. 10 and 11 is used, the optical fibers 50a and 51a are connected as follows, the optical fiber covering portions 50b and 51b are fixed, and the optical fiber cables 50 and 51 are connected. Can be fixed. In the case of this optical fiber connecting member, the fixing member 53 is opened, the fiber fixing unit 110 is attached to the cable fixing unit 120, and the gap adjusting member 4 is moved from the first position to the second position. Thus, a gap is formed between the sheet 111 and the plate 112. Then, the optical fiber cables 50 and 51 are respectively inserted from the cable insertion holes 55a from the outside of the cable fixing portions 55, and the optical fibers 50a and 51a are fixed and the optical fiber covering portions 50b and 51b in the same manner as the optical fiber connection member 100. To fix.

  Next, the fixing member 53 that has been expanded by sliding the annular portion 54 is sandwiched, and the opening angle of the fixing member 53 is maintained and fixed, and the optical fiber cables 50 and 51 are fixed. As described above, the optical fiber cables 50 and 51 can be fixed together with the optical fibers 50a and 51a and the optical fiber covering portions 50b and 51b by the optical fiber connecting members shown in FIGS. .

It is a perspective view which shows the optical fiber connection member which concerns on this Embodiment. It is the II-II sectional view taken on the line of FIG. It is a perspective view which shows the state which shifted the fiber fixing unit of the optical fiber connection member in FIG. It is a top view which shows the sheet | seat part in the optical fiber connection member of FIG. A gap adjustment member is shown, (a) is a top view and (b) is a side view. It is a perspective view which shows the fixing member which has a demon part. It is a perspective view which shows the fixing member which has a curved part. It is sectional drawing which shows the sheet | seat part from which cross-sectional shape differs, (a) is a V groove, (b) is a semicircle-shaped groove | channel, (c) has shown the sheet | seat part which each has a U-shaped groove | channel. It is a perspective view which shows the cable fixing unit which comprises another optical fiber connection member which concerns on this Embodiment. (A) is a perspective view which shows the fiber fixing unit of the optical fiber connection member shown in FIG. 9, (b) is a side view which shows the state by which the optical fiber coating | coated part is inserted in the fiber fixing unit of (a). . It is a side view which shows the connection procedure of the optical fiber by the optical fiber connection member shown in FIG. 1, (a) is a fiber fixing unit before optical fiber fixing, (b) is a fiber fixing unit after (a), (c ) Shows the fiber fixing unit after (b), and (d) shows the fiber fixing unit after (c). It is sectional drawing which shows the procedure in the middle in the connection method of the optical fiber using the optical fiber connection member shown in FIG. FIG. 13 is a cross-sectional view showing a procedure subsequent to FIG. 12.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1,111 ... Sheet | seat part, 2,112 ... Plate part 3 ... Clamp member, 4 ... Gap adjustment member 1a, 1b ... V groove 10,110 ... Fiber fixing unit 20,120 ... Cable fixing unit 22,55 ... Cable fixing part 24, 42, 53 ... fixing member 25 ... locking portion, 31 ... demon portion 41 ... curved portion, 50, 51 ... optical fiber cable 50a, 51a ... optical fiber 50b, 51b ... optical fiber covering portion 54 ... annular member 100 ... Optical fiber connection members

Claims (5)

An optical fiber connecting member having a fiber fixing part that presses and supports a glass part of an optical fiber and mechanically fixes the glass part,
Have a cable fixing portion for fixing the jacket of the optical fiber cable on both sides of the fiber fixing portion,
The cable fixing unit is disposed on both sides of a fiber fixing unit having the fiber fixing unit and a storage unit for storing the fiber fixing unit, and the storage unit and each cable fixing unit are integrated into the storage unit. A cable fixing unit formed in each cable fixing part, and a cable insertion hole that communicates , and the fiber fixing unit and the cable fixing unit are configured to be detachable ,
The fiber fixing unit has a coating fixing portion that presses and supports an optical fiber coating portion around the glass portion of the optical fiber between the fiber fixing portion and the cable fixing portion to fix the fixing portion. An optical fiber connecting member. The optical fiber according to claim 1, wherein the cable fixing portion is configured by opposingly arranging fixing members having a demon portion, and the optical fiber cable can be gripped by the demon portion of the fixing member. Connection member. Said cable fixing part is composed of a fixed member disposed face to face with a curved portion corresponding to the optical fiber cable, the curved portion of the fixing member, according to claim 1, wherein the graspable the optical fiber cable The optical fiber connection member as described. The cable fixing portion has a fixing member expandable chuck structure, the fixing member is a slidable annular member or screw member, according to claim 1, wherein the graspable fastening the optical fiber cable Optical fiber connection member. An optical fiber connection method using the optical fiber connection member according to any one of claims 1 to 4 ,
For the first and second optical fiber cables having optical fibers to be connected by the optical fiber connecting member, the respective jackets are removed, the optical fiber covering portion is removed, and then cut to a predetermined length, The first and second optical fiber cables are inserted from the cable insertion holes formed in the cable fixing portion of the optical fiber connecting member, and the glass portions of the optical fibers in the first and second optical fiber cables are inserted. When the end face hits, the glass part of each optical fiber is pressed by the fiber fixing part of the optical fiber connecting member to be positioned and supported and fixed, and each optical fiber coating part is pressed and fixed by the coating fixing part. And then fixing the outer sheath of the first and second optical fiber cables with the cable fixing portion. Server connection method.

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