JP2005326525A - Optical fiber alignment fixture - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To align individual optical fibers drawn out of an optical cable in a row. <P>SOLUTION: A movable clamp 34 is preliminarily placed near a fixed clamp 30. The optical fibers drawn out of an underwater optical cable 10 are laced through a slit 28 and through between elastic bodies 44 and 50 of the fixed clamp 30. The height of the slit 28 is as narrow as to allow an optical fiber to be laced but to prevent two optical fibers laced. The plurality of optical fibers are laced between the elastic bodies 64 and 70 of the movable clamp 34 and held with the fixed clamp 30 in an aligned state, and also held with the movable clamp 34 in an aligned state. In this state, the movable clamp 34 is moved along a guide axis 32 to be separated from the fixed clamp 30. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an optical fiber alignment jig that aligns a plurality of optical fibers for processing into a ribbon shape.

  A plurality of optical fibers are accommodated in the optical fiber cable. The optical fiber cable basically includes a tension member, a plurality of optical fibers, and a sheath that accommodates these and protects them from the outside.

  There are two types of optical fiber cables: a fixed type that holds a plurality of optical fibers to be accommodated in a cable sheath, and a loose type that gently holds the optical fiber. Recently, the loose type has attracted attention.

In a long-distance optical fiber transmission line, two optical fiber cables are connected to each other by an optical repeater. For example, an optical amplifier or the like is accommodated in the optical repeater. When a loose type optical fiber cable is used, it is not sufficient to fix the tension member to the optical repeater, and it is necessary to fix each optical fiber to the casing of the optical repeater. An apparatus for fixing a loose type optical fiber cable to an optical repeater is described in Patent Document 1.
US Pat. No. 6,438,300

  When individual optical fibers drawn from an optical cable are optically connected to an optical fiber in an optical repeater or the like, as shown in FIG. 3 of Patent Document 1, the optical fiber drawn from the optical cable is a ribbon. It is convenient to arrange them in advance.

  The present invention relates to an optical fiber alignment jig that can easily align a plurality of separated optical fibers on a single plane.

  An optical fiber alignment jig according to the present invention is a jig for aligning a plurality of separated optical fibers, a slit capable of accommodating a plurality of optical fibers drawn from an optical cable in a horizontal row, and the plurality of optical fibers Of the movable fiber holder that is linearly movable in the direction approaching and leaving the slit, and the slit and the movable fiber holder. A fiber holder disposed in between, and a fixed fiber holder that holds the plurality of optical fibers in a state of being arranged in a horizontal row so as to be movable in the axial direction of the optical fiber. To do.

  According to the present invention, a plurality of separated optical fibers can be pulled out from an optical cable in an aligned state. A plurality of optical fibers are aligned between the movable phi holder and the fixed fiber holder, and the optical fibers thus aligned can be integrated into a ribbon shape with a simple operation. Thereby, for example, the operation of connecting the optical submarine cable to the optical repeater is simplified.

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

  FIG. 1 shows a perspective view of one embodiment of the present invention, and FIG. 2 shows a perspective view seen from another direction. The jig 10 of this embodiment is used for connecting the optical submarine cable 12 to the optical repeater. Specifically, a plurality of optical files 14 drawn from the optical submarine cable 12 are ribboned. It is used to align a plurality of separated optical fibers as a premise to be bonded and integrated into a shape. For ease of understanding, the optical fiber 14 is omitted in FIG. 1, and the optical fiber 14 is shown in FIG.

  A flange 16 or a flange for locking to the jig 10 and an optical repeater (not shown) is crimped to the tip of the optical submarine cable 12. The jig 10 includes, at one end thereof, a set plate 20 having a semicircular inner surface having the same shape as the flange 16 and a semicircular support 22 pivotally supported at the lower end of the set plate 20. By sandwiching the flange 16 between the set plate 20 and the support 22, the flange 16 can be locked at that position. The support 22 can be fixed to the set plate 20 with the thumbscrew 24.

  The set plate 20 is made of aluminum for weight reduction, and the support 22 is made of MC nylon resin to reduce weight and prevent damage to the optical fiber.

  A guide plate 26 is fixed to the side surface of the set plate 20. The guide plate 26 includes a slit 28 that accommodates a plurality of, for example, eight or sixteen optical fibers 14 drawn out from the optical submarine cable 12 and arranged in a horizontal manner. FIG. 3 shows a perspective view of the guide plate 26. In FIG. 3, the hatched surface 26a is chamfered.

  FIG. 4 shows an example of the shape of the slit 28. In the example illustrated in FIG. 4, the slit 28 includes a recess 28 a that can accommodate the eight optical fibers 14 side by side. The height H of the slits 28 other than the recess 28a is set to a value slightly larger than the diameter of the optical fiber 14. The height Hmax of the recess 28 a is set to a value slightly smaller than twice the diameter of the optical fiber 14. The width W of the recess 28a is set to a desired number, for example, 8 or 16 optical fibers 14 which can be closely accommodated side by side. With this structure of the slit 28, a plurality of separated optical fibers can be easily aligned in a horizontal row.

  A clamp 30 is fixed to the back surface of the guide plate 26. Although details will be described later, the fixing clamp 30 holds the optical fiber 14 drawn out from the cable 12 and aligned in the horizontal example in place. In the present embodiment, a clamp 34 that is movable along a rectangular column-shaped guide bar 32 extending perpendicularly to the support plate 20 is further provided. The movable clamp 34 is fixed on a base 36 slidable along the guide bar 32, and the base 36 can be fixed to a desired position of the guide bar 32 by a thumbscrew 38. The holding force of the movable clamp 34 for the optical fiber 14 is set such that the movable clamp 34 can move while sliding with respect to the optical fiber 14 when moving along the guide rod 32. That is, the optical fiber holding force of the movable clamp 34 is smaller than the optical fiber holding force of the fixed clamp 30.

  An optical fiber receiving groove 40 that accommodates the plurality of optical fibers 14 in an aligned state is formed on the base 36 adjacent to the clamp 34. At least the surface of the optical fiber receiving groove 40 is made of MC nylon resin. The optical fiber receiving groove 40 is located between the fixed clamp 30 and the movable clamp 34. The width of the optical fiber receiving groove 40 is substantially the same as the width W of the recess 28 a of the slit 28. By providing the receiving groove 40, when the movable clamp 34 is moved away from the fixed clamp 30 along the guide rod 32 while holding the optical fiber 14, the alignment state of the plurality of optical fibers 14 is maintained. Can be maintained.

  FIG. 5 shows a side view of the fixed clamp 30 in the closed state, and FIG. 6 shows a side view of the fixed clamp 30 in the opened state. A metal cradle 42 is fixed to the guide plate 26, and an elastic body 44 made of a soft rubber having a hardness of 70 or less is bonded to the upper surface of the cradle 42 to protect the optical fiber 14. The movable arm 46 is supported so as to be rotatable about a pin 48 planted on the guide plate 26, and an elastic body 50 made of soft rubber is also provided on the surface of the movable arm 46 that faces the cradle 42. Is adhered. In other words, by sandwiching the optical fiber 14 between the elastic bodies 44 and 50, the fixed clamp 30 can hold the plurality of optical fibers 14 in an aligned state.

  A torsion spring 52 is wound around the pin 48. Due to the return force of the torsion spring 52, the movable arm 46 is always adjusted in the clockwise direction in FIG. The operation lever 54 abuts on the upper surface of the movable arm 46. The operation lever 54 is rotatable around a pin 56 planted on the guide plate 26. The distal end of the operation lever 54 is substantially circular, and the pin 56 is eccentrically arranged at the substantially circular portion of the distal end of the operation lever 54.

  In a state where the operation lever 54 is released, the movable arm 46 is moved to a position where the elastic body 50 comes into contact with the elastic body 44 of the cradle 42 by the return force of the torsion spring 52 as shown in FIG. . The operation lever 54 is stopped so that the stopper pin 58 does not rotate clockwise beyond a certain angle. In FIG. 5, since the optical fiber 14 is sandwiched, the elastic body 44 and the elastic body 50 are slightly separated from each other.

  When the operation lever 54 is operated counterclockwise in FIG. 5 against the force of the torsion spring 52, the movable arm 46 rotates counterclockwise around the pin 48, and the elastic body 50 moves from the elastic body 44. Leave. When the operation lever 54 is rotated by a predetermined angle or more, the operation lever 54 is stabilized at that position, and the clamp 30 is maintained in an open state. FIG. 6 illustrates this state. In the state shown in FIG. 6, the plurality of optical fibers 14 can be sequentially inserted into the slits 28 of the guide plate 26 and can be inserted between the elastic bodies 44 and 50. When the optical fiber 14 is disposed, the operation lever 54 may be released or the pin 56 may be rotated about the pin 56 in the clockwise direction. Then, the movable arm 46 rotates clockwise around the pin 48 by the force of the torsion spring 52 and returns to the state shown in FIG. In this state, the clamp 30 holds the optical fiber 14 in an aligned state between the elastic bodies 44 and 50 as shown in FIG.

  FIG. 7 shows a side view of the movable clamp 34 in the closed state, and FIG. 8 shows a side view of the movable clamp 34 in the opened state. The movable clamp 34 basically has the same structure except that the holding force of the optical fiber 14 is stronger than that of the fixed clamp 30.

  A metal cradle 62 is fixed to the base 36, and an elastic body 64 made of soft rubber having a hardness of 70 or less is bonded to the upper surface of the cradle 62 to protect the optical fiber 14. A movable arm 66 is rotatably supported around a pin 68 planted on a plate member 36 a (FIG. 1) standing up from the base 36, and is on the surface facing the cradle 62 at the tip of the movable arm 66. Also, an elastic body 70 made of soft rubber is bonded. That is, the movable clamp 34 can hold the plurality of optical fibers 14 in an aligned state by sandwiching the optical fiber 14 between the elastic bodies 64 and 70.

  A torsion spring 72 is wound around the pin 68. Due to the return force of the torsion spring 72, the movable arm 66 is always adjusted counterclockwise in FIG. An operation lever 74 abuts on the upper surface of the movable arm 66. The operation lever 74 is rotatable around a pin 76 planted on a plate member 36 a (FIG. 1) standing from the base 36. The distal end of the operation lever 74 is substantially circular, and the pin 76 is eccentrically arranged at the substantially circular portion of the distal end of the operation lever 74.

  In the state where the operation lever 74 is released, the movable arm 66 is moved to a position where the elastic body 70 contacts the elastic body 64 of the cradle 62 by the return force of the torsion spring 72 as shown in FIG. . The operation lever 74 is stopped so that the stopper pin 78 does not rotate counterclockwise beyond a certain angle. In FIG. 7, since the optical fiber 14 is sandwiched, the elastic body 64 and the elastic body 70 are slightly separated from each other.

  When the operation lever 74 is operated clockwise in FIG. 7 against the force of the torsion spring 72, the movable arm 66 rotates clockwise around the pin 68 and the elastic body 70 is separated from the elastic body 64. When the operation lever 74 is rotated by a predetermined angle or more, the operation lever 74 is stabilized at that position, and the clamp 34 is maintained in an open state. FIG. 8 illustrates this state. In the state shown in FIG. 8, a plurality of optical fibers 14 can be inserted between the elastic bodies 64 and 70. After the optical fiber 14 is disposed, the operation lever 74 may be released or the pin 76 may be rotated a little counterclockwise around the pin 76. Then, the movable arm 66 rotates counterclockwise about the pin 68 by the force of the torsion spring 72, and returns to the state shown in FIG. That is, the clamp 34 holds the optical fiber 14 firmly between the elastic bodies 64 and 70 in an aligned state.

  A method of using the present embodiment will be briefly described. Assume that a heat-shrinkable tube is used as described in Patent Document 1 and the specification and drawings of Japanese Patent Application No. 2003-010232 in order to ribbon a plurality of separated, for example, eight optical fibers. An adhesive may be used in place of or in conjunction with the heat shrink tube.

  First, the movable clamp 34 is brought closer to the fixed clamp 30 to fix the movable clamp 34 to the guide bar 32. The fixed clamp 30 and the movable clamp 34 are opened.

  The flange 16 of the optical submarine cable 12 is sandwiched between the set plate 20 and the support 22, and the support 22 is fixed to the set plate 20 with a thumbscrew 24. Thereby, the jig 10 is fixed to the end of the optical submarine cable 12.

  The optical fiber 14 is pulled out from the optical submarine cable 12 to the extent that the optical fiber 14 is sandwiched by the movable clamp 34, or the outer sheath of the optical cable 12 is peeled off by a necessary amount. The optical fibers 14 are separated from the optical cable 12 through the slit 28 and aligned in a horizontal row. The aligned optical fibers 14 are passed between the elastic bodies 44 and 50 of the fixed clamp 30, put into the receiving groove 40, and passed between the elastic bodies 64 and 70 of the movable clamp 34. With the optical fiber 14 tensioned, the fixed clamp 30 and the movable clamp 34 are closed. In this state, a plurality of, for example, eight optical fibers 14 are aligned in a horizontal row.

  The thumbscrew 38 of the guide 36 is loosened, and the movable clamp 34 is moved along the guide bar 32 in a direction away from the fixed clamp 30. The optical fiber 14 remains stationary at the position by the holding force of the fixed clamp 30, and the movable clamp 34 moves along the stationary optical fiber 14. During movement of the movable clamp 34, the recess 28a of the slit 28, the clamp by the fixed clamp 30, the fiber receiving groove 40 and the clamp by the movable clamp 34 hold the optical fiber 14 in a horizontal alignment.

  When the movable clamp 34 is separated from the fixed clamp 30 to the extent necessary for the bonding process by the adhesive, the adhesive is attached to the optical fiber 14 between the fixed clamp 30 and the movable clamp 34 and fixed to each other. Thereby, the some optical fiber 14 between the fixed clamp 30 and the movable clamp 34 is integrated in ribbon shape.

  The movable clamp 34 is opened to remove the ribbon-shaped optical fiber 14 from the movable clamp 34, and the ribbon-shaped optical fiber 14 is passed through the heat-shrinkable tube between the movable clamp 34 and the fixed clamp 30. The position of the movable clamp 34 is adjusted, and the heat shrinkable tube is positioned between the movable clamp 34 and the fixed clamp 30.

  Again, the ribbon-like optical fiber 14 is sandwiched in the movable clamp 34, and the movable clamp 34 is moved slightly away from the fixed clamp 30, so that the optical fiber 14 is held tight and the heat-shrinkable tube is heated and contracted. . As a result, the optical fibers 14 are integrated in a state of being aligned in a horizontal row to form a so-called optical fiber ribbon. Thereafter, the fixed clamp 30 and the movable clamp 34 are opened, and the optical fiber ribbon is removed from the jig 10.

  9 to 14 show other examples of the shape of the slit 28. In the example shown in FIG. 9, grooves having an inner surface along the outer shape of each optical fiber 14 are formed in the slit 28 by the number of the optical fibers 14. In other words, it is equivalent to a shape in which a protrusion for positioning each optical fiber is raised in the recess 28a having the configuration shown in FIG.

  In the example shown in FIG. 10, the height H of the slit 28 is set to a constant value that is slightly larger than the diameter of the optical fiber 14.

  The example shown in FIG. 11 shows the shape of the slit 28 for simultaneously forming two ribbons of eight. In comparison with FIG. 4, two recesses 28b and 28c capable of accommodating eight optical fibers in a horizontal row are provided. The height Hmax of the recesses 28b and 28c is set to a value slightly smaller than twice the diameter of the optical fiber 14 as in the case of FIG.

  FIG. 12 shows an example in which a convex portion 28d is raised in the slit 28 so that it can be distinguished every eight. The height of the empty space between the convex portion 28d and the ceiling of the slit 28 is set so that one optical fiber 14 can pass at a time. By bringing the optical fiber 14 to the convex portion 28d, the plurality of optical fibers 14 can be aligned in a horizontal row.

  When all the optical fibers accommodated in the optical cable 12 cannot be ribboned at a time, it is necessary to prepare a space for retracting the optical fiber to be ribboned in the second and subsequent times. FIGS. 13 and 14 show configuration examples in which such a retreat space is provided in the back of the slit 28, respectively.

  In the configuration shown in FIG. 13, a recess 28e deep enough to stack a plurality of optical fibers is provided in the back of the slit 28, and eight optical fibers are arranged horizontally in a row between the recess 28e and the entrance of the slit 28. A recess 28f having a height that can accommodate only one optical fiber is provided.

  In the configuration shown in FIG. 14, the height H between the recess 28e as the retreating place and the entrance of the slit 28 is set to a height that can accommodate only one optical fiber. A plurality of optical fibers 14 can be aligned in a horizontal row by bringing the optical fiber 14 to the convex portion 28h that becomes a wall between the concave portion 28e.

  In the above embodiment, the optical fiber holding force of the movable clamp 34 is greater than the optical fiber holding force of the fixed clamp 30, but the reverse may be possible. In that case, when moving the movable clamp 34 in the direction away from the fixed clamp 30, the optical fiber 14 clamped by the movable clamp 34 moves along with the movable clamp 34 while sliding with respect to the fixed clamp 30.

  Although the invention has been described with reference to specific illustrative embodiments, various modifications and alterations may be made to the above-described embodiments without departing from the scope of the invention as defined in the claims. This is obvious to an engineer in the field to which the present invention belongs, and such changes and modifications are also included in the technical scope of the present invention.

It is a perspective view of one Example of this invention. It is the perspective view seen from another direction of a present Example. 3 is a perspective view of a guide plate 26. FIG. It is an example of the shape of the slit. It is a side view of the fixed clamp 30 in the closed state. It is a side view of the fixed clamp 30 of the open state. It is a side view of the movable clamp 34 of the closed state. It is a side view of the movable clamp 34 of the open state. It is another example of the shape of the slit. It is another example of the shape of the slit. It is another example of the shape of the slit. It is another example of the shape of the slit. It is another example of the shape of the slit. It is another example of the shape of the slit.

Explanation of symbols

10: Jig 12: Optical submarine cable 14: Optical fiber 16: Flange 20: Set plate 22: Support 24: Knob screw 26: Guide plate 26a: Chamfered surface 28: Slits 28a, 28b, 28c: Recess 28d: Convex portions 28e, 28f: Concavity 28h: Convex portion 30: Fixed clamp 32: Guide bar 34: Movable clamp 36: Base 36a: Plate material 38: Knob screw 40: Optical fiber receiving groove 42: Receiving base 44: Elastic body 46: Movable Arm 48: Pin 50: Elastic body 52: Torsion spring 54: Operation lever 56: Pin 58: Stopper pin 62: Base 64: Elastic body 66: Movable arm 68: Pin 70: Elastic body 72: Torsion spring 74: Operation lever 76: Pin 78: Stopper pin

Claims (7)

A jig for aligning a plurality of separated optical fibers,
A slit (28) capable of accommodating a plurality of optical fibers (14) drawn from the optical cable (12) in a horizontal row;
A fiber holder that holds the plurality of optical fibers (14) in a horizontal row, and is a movable fiber holder that is linearly movable in a direction toward and away from the slit (28). 32, 34, 36, 40),
A fiber holder disposed between the slit (28) and the movable fiber holder (32, 34, 36, 40), wherein the plurality of optical fibers (14) are arranged in a horizontal row. And a fixed fiber holder (30) for holding the optical fiber so as to be movable in the axial direction.
An optical fiber alignment jig characterized by comprising:   The optical fiber alignment jig according to claim 1, wherein the fixed fiber holder (30) is disposed in close contact with the slit (28). The movable fiber holder is
A guide material (32);
A base (36) movable along the guide material (32);
Clamp (34) attached to the base (36) and capable of holding optical fibers in a horizontal row
The optical fiber alignment jig according to claim 1 or 2, further comprising:   The optical fiber alignment jig according to claim 3, wherein the movable fiber holder further comprises a fiber receiving groove (40) for receiving the plurality of optical fibers adjacent to the clamp (34).   The clamp (34) includes an elastic body (64, 70) on each of two surfaces in contact with the optical fiber, and holds the plurality of optical fibers (14) between the elastic bodies. Item 5. An optical fiber alignment jig according to Item 4.   The fixed fiber holder (30) includes a stationary pedestal (42), a movable arm (46) having one end facing the cradle (42), the cradle (42), and the movable arm (46). The elastic bodies (44, 50) respectively disposed on the surfaces facing each other, and a spring material (52) for adjusting the movable arm (46) toward the cradle (42). The optical fiber alignment jig according to any one of claims 1 to 5.   The optical fiber alignment jig according to any one of claims 1 to 6, wherein the height of the slit (28) is smaller than twice the diameter of the optical fiber.

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