JP6072125B2 - Jacket gripping member removal tool and optical fiber connection unit kit - Google Patents

Description

  The present invention relates to a jacket gripping member removal tool and an optical fiber connection unit kit for removing a jacket gripping member from a retaining housing that houses a sheath gripping member fixed to an end of an optical fiber cable.

As an optical fiber cable, there is a fiber embedded cable (for example, an optical drop cable) having a structure in which an optical fiber and a pair of strength members are embedded in a sheath having a rectangular cross section made of synthetic resin. For the fiber-embedded cable, an optical fiber connection unit such as an optical connector having a structure for holding a jacket holding member fixed to the end of the cable is used.
As an optical connector, there is an optical connector having a structure having an outer gripping member that is fixed to the end of the optical fiber cable, and a retaining housing that houses the outer gripping member (see, for example, Patent Document 1). The optical connector described in Patent Document 1 employs a latch structure that locks the jacket gripping member on the retaining housing.

International Publication No. 2013/129485

However, in the optical connector, in order to unlock the latch in order to remove the outer gripping member from the retaining housing, the latch is pressed from both sides of the retaining housing and displaced inward by a removal tool. Is required. That is, in order to remove the covering member from the retaining housing, two work spaces are required to sandwich the retaining housing outside the retaining housing. For this reason, it may be difficult to remove the outer gripping member.
The present invention has been made in view of the above circumstances, and in an optical fiber connection unit having a latch structure for locking an outer gripping member to a retaining housing, a work space for removing the outer gripping member can be reduced in a compact manner. It is an object to provide a detachable tool and an optical fiber connection unit kit.

The present invention relates to a sheath gripping member removal tool for removing the sheath gripping member from a retaining housing that houses a sheath gripping member fixed to the end of an optical fiber cable, and the retaining housing includes the sheath A latch having a locking portion that can be locked to a locking receiving portion on the outer surface of the outer cover holding member; And a release operation part extending from the base part, and the release operation part is inserted between the retaining housing and thereby split between the outer gripping member and the latch. Provided is a jacket gripping member removing tool that is inserted to displace the latch outward, thereby releasing the locking of the locking portion with respect to the locking receiving portion.
At the distal end portion of the release operation portion, a pressing portion is formed that displaces the latch outward by pressing the latch outward as the release operation portion is inserted into the retention housing. It is preferable.
The present invention further includes an engaging convex portion protruding from the base portion, and the engaging convex portion is engaged with the outer covering member to remove the outer covering member from the retaining housing. It is preferable to be able to press in the direction.
It is preferable that a protruding dimension of the engaging convex part is smaller than a protruding dimension of the release operation part.

  The present invention includes the jacket gripping member removal tool and an optical fiber connection unit, and the optical fiber connection unit includes a connection unit main body having an optical fiber connector, and a retaining portion for retaining an end of the optical fiber cable. The optical fiber connector includes an optical fiber inserted into the optical fiber connector from one side, and is drawn from the end of the optical fiber cable and inserted from the other side of the optical fiber connector. An insertion optical fiber is abutted and connected, and the retaining portion provides the optical fiber connection unit kit including the outer gripping member and the retaining housing.

  According to the present invention, the latch operating portion of the latch with respect to the latch receiving portion of the outer gripping member can be simply inserted by inserting the release operation portion into the retaining housing and inserting it between the outer gripping member and the latch. Since the stop is released, the covering member can be removed from the retaining housing. Therefore, when removing the jacket gripping member, only one working space needs to be secured outside the retaining housing. That is, the work space for removing the outer gripping member can be reduced in a compact manner. Therefore, it is possible to reduce the difficulty of the work for removing the outer gripping member.

1A is a side view of an embodiment of an outer gripping member removing tool of the present invention and an optical connector to which the removing tool can be applied. (B) It is a disassembled perspective view of the removal tool and optical connector of (A). It is a perspective view of the jacket holding member removal tool of FIG. FIG. 2 is a perspective view of an outer gripping member of the optical connector of FIG. 1. FIG. 2 is a side view of the outer gripping member removal tool and the outer gripping member of FIG. 1. (A) It is a plane sectional view of the optical connector of FIG. (B) It is a sectional side view of the optical connector of (A). (A) It is a plane sectional view of the optical connector of FIG. (B) It is a sectional side view of the optical connector of (A). (A) It is a plane sectional view of the optical connector of FIG. (B) It is a sectional side view of the optical connector of (A). It is a top view which shows the other example of the jacket holding member which can apply the jacket holding member removal tool of FIG. It is a top view which shows the example of the optical fiber connection unit which can apply the jacket holding member removal tool of FIG.

Hereinafter, an embodiment of the jacket gripping member removal tool (hereinafter also simply referred to as a removal tool) of the present invention will be described with reference to the drawings.
FIG. 1A is a side view of a removal tool 1 according to an embodiment of the present invention and an optical connector 100 to which the removal tool 1 can be applied. FIG. 1B is an exploded perspective view of the removal tool 1 and the optical connector 100.
As shown in FIGS. 1A and 1B, an optical connector 100 (optical fiber connection unit) includes a connector main body 10 (connection unit main body) and a terminal of an optical fiber cable 70 on the rear side of the connector main body 10. And a retaining portion 40 that retains. The optical connector 100 is, for example, a field assembly type optical connector.

The connector body 10 includes a body housing 11 and a ferrule 60 with a clamp portion housed in the body housing 11.
The ferrule 60 with a clamp part includes a ferrule 61 in which an optical fiber 62 (built-in optical fiber 62) is inserted and fixed, and a clamp part 63 (optical fiber connector). The built-in optical fiber 62 protrudes rearward from the ferrule 61.
The clamp part 63 can be held and fixed in a state where the built-in optical fiber 62 and the optical fiber 73 are butt-connected by a pair of elements.

An optical fiber 73 (inserted optical fiber) drawn from the end of the optical fiber cable 70 is inserted into the connector main body 10 and is butt-connected to the built-in optical fiber 62 in the clamp portion 63. Reference symbol P denotes a connection portion between the optical fiber 73 and the built-in optical fiber 62.
Hereinafter, the tip direction (left side in FIG. 1A) of the ferrule 61 of the ferrule 60 with a clamp portion may be referred to as the front, and the opposite direction may be referred to as the rear.

The retaining portion 40 includes an outer gripping member 20 that grips and fixes the end of the optical fiber cable 70, and a retaining housing 41 that houses the outer gripping member 20.
The retaining housing 41 includes a stop ring portion 42 inserted into the connector main body 10 and a square tubular gripping member receiving portion 43 extending rearward from the stop ring portion 42.

The holding member receiving portion 43 is provided between an elongated plate-like bottom plate portion 43a extending in the front-rear direction, a pair of side plate portions 43b and 43b erected on both side edges of the bottom plate portion 43a, and upper ends of the side plate portions 43b and 43b. The top plate portion 43c is formed in a cylindrical shape having a rectangular cross section.
The gripping member receiving portion 43 can store the jacket gripping member 20 in an internal space 44 surrounded by the bottom plate portion 43a, the pair of side plate portions 43b and 43b, and the top plate portion 43c. The gripping member receiving portion 43 can store and take out the outer gripping member 20 through the insertion port 45 that is an opening on the rear end side.

As shown in FIG. 1B and FIG. 5A, rectangular openings 47 and 47 are formed in the pair of side plate portions 43b and 43b, respectively. On the front edges 47a and 47a of the openings 47 and 47, latches 48 and 48 extending rearward are formed. The latches 48, 48 are provided on the elongated plate-like latch bodies 49, 49 extending rearward from the front edges 47 a, 47 a of the openings 47, 47, and the leading ends of the latch bodies 49, 49 in the extending direction. And claw portions 50, 50.
The side plate portions 43b and 43b are arranged on the outer surface side of the side wall portions 22 and 23 of the jacket gripping member 20 described later (outside in the arrangement direction of the side wall portions 22 and 23).

The latch bodies 49, 49 can be elastically bent and deformed in the width direction of the gripping member receiving portion 43 (the arrangement direction of the pair of side plate portions 43b, 43b). The locking claws 50 and 50 (locking portions) are formed so as to protrude inward from the inner surfaces of the side plate portions 43b and 43b. The locking claw portion 50 can be engaged with one end edge 28 a (or the other end edge 28 b) of the locking recess 28 (locking receiving portion) of the jacket gripping member 20. The locking claw portion 50 can restrict the rearward movement of the outer gripping member 20 accommodated in the gripping member receiving portion 43 by engaging with the one end edge 28 a (or the other end edge 28 b) of the locking recess 28. it can.
The front surface 50 a of the locking claw 50 is a surface facing forward, and is an engagement surface that engages with one end edge 28 a of the locking recess 28. The front surface 50 a of the locking claw 50 may be, for example, an inclined surface that increases in protruding height toward the front, or a surface that is perpendicular to the inner surface of the latch body 49. The rear surface 50b of the locking claw portion 50 may be, for example, an inclined surface that decreases the protruding height toward the rear.

As shown in FIGS. 1B and 5B, the upper surface 43c1 (outer surface) of the top plate portion 43c is a flat surface.
A pair of insertion slits 51, 51 are formed in the top plate portion 43c with an interval in the width direction (Y direction). The insertion slits 51 and 51 are openings for inserting the release operation portions 3 and 3 and the engagement convex portions 4 and 4 of the removal tool 1 to be described later, and in the length direction (X direction) of the top plate portion 43c. It is formed to extend.
The insertion slits 51 and 51 are formed at positions on one side and the other side of the center in the width direction (Y direction), respectively, and at least a part of the insertion slits 51 and 51 is formed in the vertical direction ( Z direction).
The top plate portion 43c is formed with a confirmation slit 52 at the center position in the width direction (Y direction) where the optical fiber 73 in the gripping member receiving portion 43 can be seen. The confirmation slit 52 is formed to extend in the length direction (X direction) of the top plate portion 43c. Through the confirmation slit 52, it is possible to confirm the bending generated in the optical fiber 73.

  A tapered recess 43 d is formed in the front portion of the gripping member receiving portion 43 so as to face the internal space 44 and is recessed in a tapered shape from the rear end toward the front side. A rear end of the fiber introduction hole 42a for guiding the optical fiber 73 into the connector body 10 is opened at the front end of the tapered recess 43d. The tapered recess 43d guides the tip of the optical fiber 73 and facilitates insertion into the fiber introduction hole 42a.

  As shown in FIG. 1B, the bottom surface (inner surface) of the rear portion of the top plate portion 43c is pressed to press the end of the optical fiber cable 70 held by the jacket holding member 20 housed in the internal space 44. A portion 46 is formed to protrude downward.

As shown in FIG. 3, the jacket gripping member 20 includes a bottom wall portion 21 and a pair of side walls formed on both side edges of the bottom wall portion 21 standing on the bottom wall portion 21 with a space therebetween. Parts 22 and 23. The jacket holding member 20 is, for example, an integrally molded product made of plastic.
The bottom wall portion 21 is formed in, for example, a rectangular plate shape in plan view.
The side wall portions 22 and 23 are formed on the upper surface side of the bottom wall portion 21 so as to protrude upward (Z direction) perpendicular to the bottom wall portion 21. The pair of side wall portions 22 and 23 are formed over the entire length of the bottom wall portion 21 along one and the other side edges of the bottom wall portion 21.

A groove portion 24 is defined between the pair of side wall portions 22 and 23. Both ends in the longitudinal direction (X direction) of the groove portion 24 are opened (opened).
The groove portion 24 is formed at one end portion in the longitudinal direction of the first cable groove 24A into which the first optical fiber cable 71 is fitted, and the second optical fiber cable 72 is formed at the other end portion of the groove portion 24 in the longitudinal direction. A second cable groove 24B to be fitted.

The second optical fiber cable 72 has a smaller cross-sectional size than the first optical fiber cable 71.
The first cable groove 24A is formed to reach one end 21h in the longitudinal direction of the bottom wall portion 21 (an end on the near side in FIG. 3), and is opened (opened) at the one end 21h. The first cable groove 24 </ b> A is formed to extend in the longitudinal direction (X direction) of the bottom wall portion 21.
The second cable groove 24B is formed to reach the other end 21i in the longitudinal direction of the bottom wall portion 21 (end on the back side in FIG. 3), and is opened (opened) at the other end 21i. The second cable groove 24 </ b> B extends in the longitudinal direction of the bottom wall portion 21.

The cross-sectional size of the second cable groove 24B orthogonal to the longitudinal direction of the groove portion 24 is smaller than the cross-sectional size of the first cable groove 24A. Therefore, the end of the first optical fiber cable 71 can be fitted into the first cable groove 24A. The end of the second optical fiber cable 72 can be fitted into the second cable groove 24B.
The terminal of the optical fiber cable 70 (71, 72) and the jacket holding member 20 fixed to the terminal may be collectively referred to as a cable terminal 76 with a holding member.

On the inner surfaces 22a and 23a of the side wall portions 22 and 23 forming a pair of inner surfaces of the first cable groove 24A, grip claws 25 and 25 (hereinafter referred to as first grips) extending in the depth direction of the first cable groove 24A, respectively. (Also referred to as a claw 25). The first gripping claws 25 are, for example, protrusions having a substantially triangular cross section whose width gradually decreases in the protruding direction.
A plurality of first gripping claws 25, 25 are arranged at intervals in the longitudinal direction of the first cable groove 24A (groove portion 24). The first gripping claws 25, 25 are arranged at positions facing each other through the first cable groove 24A.

On the inner surfaces 22b and 23b of the side wall portions 22 and 23 forming the pair of inner side surfaces of the second cable groove 24B, grip claws 26 and 26 (hereinafter referred to as second grips) extending in the depth direction of the second cable groove 24B, respectively. The claw 26 is also projected. The second gripping claw 26 is, for example, a protrusion having a substantially triangular cross section whose width gradually decreases in the protruding direction.
A plurality of second gripping claws 26, 26 are arranged at intervals in the longitudinal direction of the second cable groove 24B (groove portion 24). The second gripping claws 26 and 26 are arranged at positions facing each other via the second cable groove 24B.
The inner surfaces 22a and 23a facing each other through the first cable groove 24A are also called first inner side surfaces 22a and 23a, and the inner surfaces 22b and 23b facing each other through the second cable groove 24B are both second inner side surfaces 22b and 23b. Sometimes called.

The separation distance between the first inner side surfaces 22a, 23a of the first cable groove 24A (the groove width W1 of the first cable groove 24A) is set to be equal to or slightly larger than the width dimension of the first optical fiber cable 71. . The separation distance between the first gripping claws 25 facing each other in the groove width direction of the first cable groove 24 </ b> A is set slightly smaller than the width dimension of the first optical fiber cable 71.
The groove width W2 of the second cable groove 24B is smaller than the groove width W1 of the first cable groove 24A. The groove width centers of the first cable groove 24A and the second cable groove 24B coincide with each other.

  The first gripping claws 25 bite into the jacket 75 of the first optical fiber cable 71 pushed into the first cable groove 24A from both sides thereof. The first optical fiber cable 71 is fixed to the outer gripping member 20 by being gripped from both sides by the first gripping claws 25. The first gripping claws 25 ensure the cable holding force of the first optical fiber cable 71 against the outer gripping member 20, that is, the rear side of the first optical fiber cable 71 relative to the outer gripping member 20 (one end side of the groove 24). It contributes effectively to securing the resistance to movement.

  The separation distance between the second inner side surfaces 22b and 23b of the second cable groove 24B (the groove width W2 of the second cable groove 24B) is set to be equal to or slightly larger than the width dimension of the second optical fiber cable 72. . The separation distance between the second gripping claws 26 facing each other in the groove width direction of the second cable groove 24 </ b> B is set slightly smaller than the width dimension of the second optical fiber cable 72.

  The second gripping claws 26 bite into the jacket 75 of the second optical fiber cable 72 pushed into the second cable groove 24B from both sides thereof. The second optical fiber cable 72 is fixed to the jacket gripping member 20 by being gripped from both sides by the second gripping claws 26. The second gripping claw 26 secures the cable holding force of the second optical fiber cable 72 against the outer gripping member 20, that is, the rear side of the second optical fiber cable 72 relative to the outer gripping member 20 (the other end side of the groove 24). It contributes effectively to securing the resistance to movement.

The groove portion 24 of the jacket gripping member 20 is a fiber accommodation groove in which the optical fiber 73 of the first optical fiber cable 71 or the second optical fiber cable 72 is accommodated between the first cable groove 24A and the second cable groove 24B. 30.
The fiber accommodation groove 30 is formed to extend in the longitudinal direction of the bottom wall portion 21 and communicates the first cable groove 24A and the second cable groove 24B. The fiber accommodation groove 30 is formed narrower than the first cable groove 24A and the second cable groove 24B.
The fiber accommodation groove 30 has an introduction part 30a opened upward and a main groove part 30b having a narrower width than the introduction part 30a. The main groove 30b is formed downward from the bottom of the introduction part 30a.

As shown in FIG. 3 and FIG. 5 (A), a locking recess is formed at the approximate center in the longitudinal direction of the side walls 22, 23 of the outer surfaces of the side walls 22, 23 facing outward in the width direction of the jacket gripping member 20. 28, 28 are formed. The locking recesses 28 are opened on the upper and lower surfaces of the side walls 22 and 23. That is, the locking recesses 28 and 28 are formed over the entire height direction of the side walls 22 and 23.
The locking recess 28 is a recess having a fixed depth that is recessed from the outer surface of the side walls 22, 23 to the inside in the width direction of the jacket gripping member 20, and is locked to the locking claw 50 of the latch 48 of the retaining housing 41. .

One end edge 28a located on the second cable groove 24B side of the locking recess 28 is in a state in which the sheath holding member 20 attached to the first optical fiber cable 71 is accommodated in the retaining housing 41. It can be locked to the front surface 50 a of the locking claw portion 50. The one end edge 28a may be, for example, an inclined surface that is inclined forward as it goes in the depth direction of the locking recess 28, or a surface parallel to the depth direction of the locking recess 28 (perpendicular to the side bottom surface 28c). It may be a good surface).
The other end edge 28b located on the first cable groove 24A side of the locking recess 28 is latched in a state in which the sheath holding member 20 attached to the second optical fiber cable 72 is accommodated in the retaining housing 41. Can be locked to the front surface 50 a of the locking claw portion 50. The other end edge 28b may be, for example, an inclined surface similar to the one end edge 28a or a surface parallel to the depth direction of the locking recess 28.

  The dimension in the X direction of the locking recess 28 is desirably larger than the dimension in the same direction of the release operation unit 3 (see FIGS. 4 and 5B) of the removal tool 1 described later. As a result, the release operation portion 3 inserted in the rear portion of the locking recess 28 moves forward relative to the outer gripping member 20, so that the rear surface 50 b of the locking claw portion 50 is moved forward by the front edge of the release operation portion 3. It can also be displaced outwardly by pressing.

  In the illustrated example, the locking claw portion 50 (locking portion) which is a convex portion formed on the gripping member receiving portion 43 is locked to the locking recess 28 (locking receiving portion) of the outer gripping member 20. However, on the contrary, a structure in which the convex portion (locking receiving portion) formed on the outer gripping member 20 is locked to the concave portion (locking portion) formed in the holding member receiving portion 43 is adopted. May be.

On the outer surfaces of the side walls 22 and 23, first engaging recesses 31 and 31 are formed at positions on one side in the longitudinal direction (X direction) with respect to the locking recesses 28 and 28, respectively.
The first engaging recesses 31, 31 are recesses having a fixed depth formed at positions including the upper edges of the side wall portions 22, 23, and have the posture shown in FIG. 4 (the first cable groove 24 </ b> A is directed rearward). In the posture), the first engaging recesses 31 are formed in front portions of the side walls 22 and 23. For this reason, the first engaging recesses 31, 31 are positioned in front of the locking recesses 28, 28 and spaced from the locking recesses 28, 28.

While the first engaging recesses 31 and 31 are formed at the upper portions of the side wall portions 22 and 23, the lower portion of the latch 48 is at a lower position than the first engaging recess 31. 50 cannot enter the engaging recess 31.
An edge 31a located at the rear end of the first engagement recess 31 can be engaged with a rear edge 4a of an engagement convex portion 4 of the removal tool 1 described later. The edge 31a can be a surface perpendicular to the side bottom surface 31b of the first engagement recess 31, for example.

On the outer surfaces of the side walls 22, 23, second engaging recesses 32, 32 are formed at positions on the other side in the longitudinal direction with respect to the locking recesses 28, 28.
The second engagement recesses 32, 32 are recesses having a fixed depth formed at positions including the upper edges of the side wall portions 22, 23, and are in the posture shown in FIG. 4 (the first cable groove 24A is directed rearward). In the posture), the second engaging recesses 32 and 32 are formed in the rear portions of the side wall portions 22 and 23. For this reason, the second engaging recesses 32, 32 are located behind the locking recesses 28, 28 and spaced from the locking recesses 28, 28.
Similar to the first engagement recesses 31, 31, the second engagement recesses 32, 32 are formed at a height position where the latching claw portion 50 of the latch 48 cannot enter.

  When the outer gripping member 20 is in a posture in which the second cable groove 24B is directed rearward, the end edge 32a located at the front end of the second engagement recess 32 is the rear edge 4a of the engagement protrusion 4 of the removal tool 1. Can be engaged. The end edge 32a can be a surface perpendicular to the side bottom surface 32b of the second engagement recess 32, for example.

Next, a method for attaching the optical connector 100 to the end of the optical fiber cable 70 (first optical fiber cable 71) will be described.
As shown in FIGS. 1A and 1B, an insertion tool in which an insertion piece (not shown) is inserted between a pair of elements of the clamp part 63 of the ferrule 60 with a clamp part of the optical connector 100. Prepare an attached optical connector.
The outer gripping member 20 is attached to the end of the first optical fiber cable 71 by fitting the end of the first optical fiber cable 71 into the first cable groove 24 </ b> A. The optical fiber 73 passes through the fiber housing groove 30 and extends further forward through the second cable groove 24B. Thereby, the cable terminal 76 with a holding member is obtained.

As shown in FIG. 1B, the cable terminal 76 with the gripping member is inserted into the gripping member receiving portion 43 from the insertion port 45. At this time, the outer cover gripping member 20 abuts on the rear surface 50b (see FIG. 5A) of the latching claw portion 50 of the latch 48, and the latch 48 is pushed outward.
As shown in FIG. 5A, when the jacket gripping member 20 is further moved forward, the entire jacket gripping member 20 is accommodated in the gripping member receiving portion 43 and the locking claw portion 50 is locked into the locking recess. 28, and the latching claw 50 is inserted into the latching recess 28 by the elastic repulsive force of the latch 48 and latched to the one end edge 28a.
As a result, the outer gripping member 20 is fixed to the gripping member receiving portion 43. The position of the outer gripping member 20 is referred to as a storage position.

  As shown in FIGS. 1A and 5A, the optical fiber 73 protruding from the end of the optical fiber cable 70 is inserted into the clamp part 63 of the ferrule 60 with a clamp part through the fiber introduction hole 42a, A bare optical fiber 73 a of the fiber 73 is butt-connected to the built-in optical fiber 62.

  When the outer gripping member 20 reaches the storage position, the optical fiber 73 is bent and deformed in the gripping member receiving portion 43. As a result, a sufficient butting force is applied to the optical fiber 73.

As shown in FIG. 1A, after the optical fiber 73 is butt-connected to the built-in optical fiber 62, the insertion piece (not shown) is removed from the clamp portion 63. As a result, the pair of elements of the clamp part 63 are closed, and the built-in optical fiber 62 and the optical fiber 73 are gripped and fixed in a butt-connected state. Therefore, the butt connection state of the optical fiber 73 (bare optical fiber 73a) with respect to the built-in optical fiber 62 of the clamp part 63 can be kept stable.
Thus, the attachment of the optical connector 100 to the terminal of the first optical fiber cable 71 is completed.

In addition, when attaching the optical connector 100 to the terminal of the second optical fiber cable 72, instead of the first optical fiber cable 71, by fitting the terminal of the second optical fiber cable 72 into the second cable groove 24B, The jacket holding member 20 is attached to the end of the second optical fiber cable 72.
Other procedures are the same as those for attaching the optical connector 100 to the terminal of the first optical fiber cable 71.

Next, a method for removing the outer gripping member 20 from the retaining housing 41 using the removal tool 1 will be described.
First, the removal tool 1 will be described with reference to FIGS. 2 and 4. FIG. 2 is a perspective view of the removal tool 1. FIG. 4 is a side view of the removal tool 1 and the jacket gripping member 20.

  In the following description, the XYZ coordinate system shown in FIG. 2 may be referred to. Specifically, the direction in which the pair of release operation units 3 and 3 are arranged in a plane orthogonal to the thickness direction of the plate-like base unit 2 is defined as a Y direction. The direction perpendicular to the thickness direction of the base body 2 and the Y direction is taken as the X direction. A direction orthogonal to the X direction and the Y direction is defined as a Z direction. The Z direction is also referred to as the vertical direction. The release operation parts 3 and 3 side is the lower side with respect to the base body part 2. In addition, the upper and lower directions here do not limit the direction at the time of use of the removal tool 1.

As shown in FIGS. 1 and 2, the removal tool 1 includes a base portion 2, a pair of release operation portions 3 and 3 extending from the lower surface 2 a of the base portion 2, and a pair protruding from the lower surface 2 a of the base portion 2. Engaging projections 4 and 4.
The base portion 2 is, for example, a plate having a substantially rectangular shape in plan view. The base portion 2 shown in FIG. 2 is rectangular in plan view.
An anti-slip uneven portion 5 is formed on the upper surface 2 b (outer surface) of the base portion 2. The non-slip uneven portion 5 includes a plurality of grooves 5a and a plurality of protrusions 5b extending in the width direction (Y direction) in a partial region including the center of the base portion 2 in the length direction (X direction). .
As will be described later, the non-slip uneven portion 5 increases the frictional resistance of the upper surface 2b of the base portion 2 against the operator's fingers and the like when the removal tool 1 and the outer gripping member 20 are slid in the X direction. it can.

  A confirmation window 7 through which the optical fiber 73 in the gripping member receiving portion 43 can be viewed is formed in the approximate center of the base portion 2. With the confirmation window 7, it is possible to confirm the bending that has occurred in the optical fiber 73.

The release operation portions 3 and 3 are formed to extend downward (Z direction) perpendicular to the lower surface 2 a of the base portion 2. The release operation units 3 and 3 are formed in a columnar shape having a substantially rectangular cross section. The two release operation parts 3 and 3 are arranged at intervals in the Y direction.
Press surfaces 6 and 6 that are inclined with respect to the extending direction of the release operation units 3 and 3 are formed at the distal ends of the release operation units 3 and 3.
The pressing surface 6 includes an outer inclined surface 6 a formed from the front end surface 3 a of the release operation unit 3 to the outer side surface 3 b of the release operation unit 3 facing outward in the width direction of the base unit 2, and the front end surface 3 a of the release operation unit 3. And a front inclined surface 6b formed from the front surface 3c to the front surface 3c. The front inclined surface 6b is an adjacent inclined surface adjacent to the outer inclined surface 6a.

The outer inclined surface 6a is inclined closer to the inner side (the direction approaching the center in the width direction of the base body 2) toward the distal end side in the extending direction of the release operation unit 3. The front inclined surface 6b is inclined closer to the rear side toward the distal end side in the extending direction of the release operation unit 3.
Therefore, the pressing edge portion 6c (pressing portion) that is the boundary between the outer inclined surface 6a and the front inclined surface 6b is inclined toward the rear side and toward the inner side toward the distal end side in the extending direction of the release operation unit 3. ing.
As will be described later, the pressing edge portion 6c is formed so that the latching claw portion 50 of the latch 48 moves outward (in the width direction outward direction of the retaining housing 41) as the release operation portion 3 is inserted into the retaining housing 41. The locking claw portion 50 is pressed so as to be displaced in the direction (see FIGS. 5 and 6).

The engaging protrusions 4 and 4 are formed to protrude downward (Z direction) perpendicular to the lower surface 2 a of the base body 2. The engaging convex parts 4 and 4 are formed in a substantially rectangular cross section. The two engagement convex parts 4 and 4 are arranged at intervals in the Y direction.
The engagement convex portions 4 and 4 are positioned in front of the release operation portions 3 and 3. The engagement convex portion 4 can be engaged with the first engagement concave portion 31 of the outer cover gripping member 20, and the outer gripping member 20 can be pressed rearward by engaging with the first engagement concave portion 31. (See FIGS. 6 and 7).

  The projecting dimension of the engaging convex part 4 (from the lower surface 2a of the base body part 2) is preferably smaller than the extending dimension (from the lower surface 2a) of the release operation part 3. Accordingly, the engaging convex portion 4 and the release operation portion 3 are easily identified by visual observation, so that an operator can easily grasp the posture of the removal tool 1 with respect to the outer gripping member 20 and the retaining housing 41. Therefore, it is possible to prevent an erroneous operation due to a mistake in the front and rear of the removal tool 1.

Next, an operation of removing the jacket gripping member 20 from the retaining housing 41 using the removal tool 1 will be described.
As shown in FIG. 1B, the removal tool 1 is lowered toward the retaining housing 41. Accordingly, as shown in FIGS. 5A and 5B, the release operation portion 3 is inserted into the gripping member receiving portion 43 through the insertion slit 51 and comes into contact with the locking claw portion 50 of the latch 48. .
Specifically, as shown in the enlarged view in the upper right of FIG. 5A, the pressing edge 6c of the pressing surface 6 of the release operation portion 3 abuts on the upper edge 50b1 of the rear surface 50b of the locking claw portion 50. In this enlarged view, a section of the release operation portion 3 at a height position where the release operation portion 3 is in contact with the locking claw portion 50 is shown.
As shown in FIG. 2, the pressing edge 6 c is inclined toward the rear side and toward the inner side toward the distal end side in the extending direction of the release operation unit 3, so that the enlarged view of FIG. As shown, the rear end 50b contacts the rear surface 50b of the locking claw 50 at a position relatively rearward and inward.

Thereafter, as shown in FIGS. 6 (A) and 6 (B), when the removal tool 1 is further lowered by pressing the base portion 2 downward or the like, the enlarged view in the upper right of FIG. 6 (A) is obtained. As shown, the pressing edge portion 6c comes into contact with the locking claw portion 50 at a position relatively closer to the front side and closer to the outer side according to the inclination of the pressing edge portion 6c. Displace outward.
As a result, the distal end portion of the release operation unit 3 is inserted between the outer cover gripping member 20 and the latch 48.

Since the rear surface 50b of the locking claw portion 50 with which the pressing edge portion 6c abuts is an inclined surface that is closer to the outer side toward the rear, the obliquely forward force received from the pressing edge portion 6c efficiently acts on the rear surface 50b. .
Due to the outward displacement of the locking claw 50, the locking claw 50 is unlocked from the one end edge 28a of the locking recess 28.

As shown in FIG. 6B, as the removal tool 1 is lowered, the engaging convex portion 4 is inserted into the first engaging concave portion 31, and can be engaged with the end edge 31a.
As shown by arrows in FIGS. 6A and 6B, a finger or the like is applied to the upper surface 2b of the base 2 to press the base 2 backward. At this time, if the place to which a finger or the like is applied is the non-slip uneven portion 5, the backward pressing force against the base portion 2 can be increased, and the reliability of the detachment operation of the outer gripping member 20 can be increased.
When the base body portion 2 is pressed rearward, the engaging convex portion 4 engages with the end edge 31a of the first engaging concave portion 31, and the engaging convex portion 4 causes the first engaging concave portion 31 (outer gripping member) to be engaged. 20) A backward force is applied to the edge 31a.

As shown in FIGS. 7 (A) and 7 (B), when the rearward force is applied to the edge 31a of the first engagement recess 31 by the engagement protrusion 4, the removal tool 1 moves rearward. To do. At this time, the removal tool 1 may slide on the upper surface 43c1 in a state where the lower surface 2a of the base portion 2 is in contact with the upper surface 43c1 of the top plate portion 43c of the housing 41 for retention.
As the removal tool 1 moves, the jacket gripping member 20 moves backward (in the removal direction). Accordingly, the outer gripping member 20 can be taken out from the gripping member receiving portion 43 through the insertion port 45.

  As described above, according to the above-described removal tool 1, the release operation unit 3 is inserted into the retaining housing 41 and only inserted between the outer cover holding member 20 and the latch 48. Since the latching claw 50 of the latch 48 is released from the latching recess 28, the outer gripping member 20 can be removed from the retaining housing 41. For this reason, when removing the jacket gripping member 20, only one work space needs to be secured on the outside (upper side) of the retaining housing 41. That is, the work space for removing the jacket gripping member 20 can be reduced in a compact manner. Therefore, it is possible to reduce the difficulty in removing the outer cover gripping member 20.

Further, according to the above removal tool 1, simply by inserting the release operation part 3 into the retaining housing 41, the pressing edge 6c formed at the tip of the release operation part 3 presses the latch outward. Displace the latch outward. Therefore, the locking claw portion 50 of the latch 48 can be easily released from the locking recess 28 of the outer gripping member 20.
Moreover, according to the said removal tool 1, the press edge part 6c is formed so that it may incline with respect to the extension direction of the cancellation | release operation part 3, and the press edge part 6c presses the latch 48 according to the inclination, and is outward. Since it is displaced, the latch 48 can be displaced smoothly.

Moreover, since the said removal tool 1 has the engagement convex part 4, hold | maintaining the state which the latch 48 of the latch 48 was cancelled | released by the cancellation | release operation part 3, and the outer covering holding member 20 by the engagement convex part 4 is a removal direction. It can be moved (backward).
Therefore, the removal of the jacket gripping member 20 from the retaining housing 41 can be easily realized by a series of operations in which the removal tool 1 is inserted into the retaining housing 41 and moved backward.

  The jacket gripping member 20 and the optical connector 100 constitute an optical connector kit (optical fiber connection unit kit).

The technical scope of the present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.
The number of the release operation part 3 and the engagement convex part 4 should just respond | correspond at least to the number of the latching recessed parts 28 of the jacket holding member 20, and the latching claw part 50 of the housing 41 for retention, for example, may be one. 3 or more.

1 has a first cable groove 24A formed at one end portion of the groove portion 24 and a second cable groove 24B formed at the other end portion. The configuration may be such that there is no cable groove at one end of the cable groove.
In the jacket holding member 120 shown in FIG. 8, the second cable groove is not provided at the other end of the groove 24 (the left portion in FIG. 8). A space 33 between the side wall portions 22 and 23 at the other end of the groove portion 24 is an optical fiber wiring space through which the inserted optical fiber drawn from the end of the optical fiber cable held by the first cable groove 24A passes.

In the above embodiment, the removal tool 1 is applied to the optical connector 100 as shown in FIG. 1A, but the application destination of the removal tool of the present invention is not limited to the optical connector. For example, instead of the clamp part 63 shown in FIG. 1A, an optical fiber connector such as a mechanical splice may be used.
The optical fiber connection unit 110 shown in FIG. 9 includes a connection unit main body 80 having a mechanical splice 83 (optical fiber connector) and a retaining portion 40. The mechanical splice 83 can butt-connect the optical fiber 82 inserted from one side and the optical fiber 73 inserted from the other side.
In the above embodiment, the insertion direction of the release operation unit 3 with respect to the retaining housing 41 is downward (a direction perpendicular to the extending direction of the latch 48). However, the insertion direction is not limited to this, and for example, the latch 48 It is good also as a direction which cross | intersects the extending direction.

  DESCRIPTION OF SYMBOLS 1 ... Outer gripping member removal tool, 2 ... Base | substrate part, 3 ... Release operation part, 4 ... Engagement convex part, 6c ... Pressing edge part (pressing part), 20,120 ... Outer gripping member, 28 ... Locking Recessed part (locking receiving part), 41 ... Housing for retention, 43b, 43b ... Side plate part, 48 ... Latch, 50 ... Locking claw part (locking part), 70 ... Optical fiber cable, 71 ... First optical fiber cable 72 ... second optical fiber cable, 73 ... optical fiber (insertion optical fiber), 82 ... optical fiber, 100 ... optical connector (optical fiber connection unit), 110 ... optical fiber connection unit.

Claims (5)

A jacket gripping member removal tool for removing the jacket gripping member from a housing for holding a sheath gripping member fixed to the end of an optical fiber cable,
The dwelling housing has a side plate portion located on the outer surface side of the outer gripping member, and the side plate portion can be locked to a locking receiving portion on the outer surface of the outer gripping member. A latch having a portion is formed,
A base part, and a release operation part extending from the base part,
The release operation part is inserted into the retaining housing, thereby being inserted between the outer gripping member and the latch and displacing the latch outward, thereby the latch receiving part. An outer gripping member removing tool for releasing the locking of the locking portion with respect to.   At the distal end portion of the release operation portion, a pressing portion is formed that displaces the latch outward by pressing the latch outward as the release operation portion is inserted into the retention housing. The jacket gripping member removal tool according to claim 1. And further having an engaging projection protruding from the base portion,
3. The outer gripping member removal according to claim 1, wherein the engagement convex portion can be pressed in a direction in which the outer gripping member is removed from the retaining housing by being engaged with the outer gripping member. tool.   The jacket gripping member removing tool according to claim 3, wherein a protruding dimension of the engaging convex part is smaller than a protruding dimension of the release operation part. The jacket gripping member removal tool according to any one of claims 1 to 4, and an optical fiber connection unit.
The optical fiber connection unit includes a connection unit main body having an optical fiber connector, and a retaining portion for retaining an end of the optical fiber cable.
The optical fiber connector includes an optical fiber inserted into the optical fiber connector from one side, and an inserted optical fiber drawn from the end of the optical fiber cable and inserted from the other side of the optical fiber connector. And butt-connect,
The retaining portion is an optical fiber connection unit kit having the outer gripping member and the retaining housing.

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