JP7227826B2 - Manufacturing method of blade body for optical fiber cutter - Google Patents

Description

The present invention relates to a method for manufacturing a blade body for an optical fiber cutter.

In general, a fiber cutter for cutting an optical fiber cuts the optical fiber by forming an initial scratch on the optical fiber with a blade and growing the initial scratch to cleave the optical fiber (see, for example, Patent Documents 1 to 3). ).

JP-A-62-194204 JP 2014-238574 A JP 2018-194598 A

Japanese Patent Laid-Open No. 2002-200002 describes forming a blade body that forms an initial scratch on an optical fiber by attaching a polishing sheet having abrasive grains. However, when the blade is configured in this manner, abrasive grains are arranged not only on the edge line of the blade but also on a wide area of the side surface of the blade.

On the other hand, the cut surface (cleavage surface) of the optical fiber may be inclined by forming an initial flaw in the optical fiber while applying torsional stress or bending stress to the optical fiber. If the optical fiber is cut while applying bending stress to the optical fiber, the elastic deformation of the optical fiber returns after cutting, and the cut surface of the optical fiber may come into contact with the side surface of the blade (described later). Therefore, if the abrasive grains are arranged in a wide area on the side surface of the blade, the cut surface of the optical fiber immediately after cutting will come into contact with the abrasive grains on the side surface of the blade, which may damage the cut surface. .

An object of the present invention is to prevent the cut surface of an optical fiber from coming into contact with abrasive grains immediately after cutting.

The first main invention for achieving the above object comprises the steps of preparing a holder on which a cutting edge is provided, and forming a cutting edge formed with an adhesive containing abrasive grains at the tip of the holder. A method for manufacturing a blade body for an optical fiber cutter characterized by performing the following steps.
A second main aspect of the invention for achieving the above object comprises the steps of preparing a holder, applying an adhesive containing abrasive grains to the tip of the holder, and applying an adhesive agent to the holder. removing the applied adhesive and forming a cutting edge portion at the tip portion.
A third main aspect of the invention for achieving the above object is to provide a step of preparing a holder, and forming a cutting edge portion at the tip portion of the holder with an adhesive containing abrasive grains. a step of forming a coating portion covering the proximal end side of the blade body for an optical fiber cutter.

Other features of the present invention will be clarified by the description of the specification and drawings described later.

According to the present invention, an optical fiber can be cut so that the cut surface is inclined at a predetermined angle.

FIG. 1 is a perspective view of the fiber cutter 100. FIG. FIG. 2 is an exploded perspective view of the fiber cutter 100. FIG. 3A to 3C are explanatory diagrams of the operation of the fiber cutter 100. FIG. 4A to 4C are schematic explanatory diagrams of the fiber cutter 100. FIG. FIG. 5A is an explanatory diagram of how the blade 47 forms an initial scratch on the optical fiber 1 to which bending stress is applied. FIG. 5B is an explanatory diagram of the blade body 47 of the reference example. FIG. 6A is an explanatory diagram of a method for manufacturing the blade body 47 of the first embodiment. FIG. 6B is an explanatory diagram of a method for manufacturing the blade body 47 of the second embodiment. FIG. 7A is an explanatory diagram of a method for manufacturing the blade body 47 of the third embodiment. FIG. 7B is an explanatory diagram of a method for manufacturing the blade body 47 of the fourth embodiment. FIG. 8A is an explanatory diagram of a method for manufacturing the blade body 47 of the fifth embodiment. FIG. 8B is an explanatory diagram of a method for manufacturing the blade body 47 of the sixth embodiment. FIG. 8C is an explanatory diagram of a method for manufacturing the blade body 47 of the seventh embodiment. FIG. 9 is an explanatory view showing how the blade body 47 manufactured by the manufacturing method of the sixth embodiment is used to cut the optical fiber 1 to which the bending stress is applied. FIG. 10A is an explanatory diagram of a method for manufacturing the blade body 47 of the eighth embodiment. FIG. 10B is an explanatory diagram of a method for manufacturing the blade body 47 of the ninth embodiment.

At least the following matters will become clear from the description of the specification and drawings described later.

A blade body for an optical fiber cutter, characterized by performing the steps of: preparing a holder having a cutting edge; The manufacturing method of is clarified. According to such a manufacturing method, it is possible to narrow the area where the abrasive grains are arranged on the side surface of the blade.

It is desirable to form the cutting edge portion by molding the adhesive containing the abrasive grains. Thereby, a sharp cutting edge can be formed.

When molding the adhesive containing the abrasive grains, it is preferable that the tip portion of the holding body is placed in the mold, and the cutting edge portion is fixed to the tip portion of the holding body during molding. . Thereby, the manufacturing process of the blade can be simplified.

It is preferable that the holding member has a mounting portion that clamps the side surface of the cutting edge portion, and that the cutting edge portion is mounted on the mounting portion after molding the cutting edge portion. As a result, since the abrasive grains on the side surface of the cutting edge portion are covered with the mounting portion, it is possible to narrow the area where the abrasive grains are arranged on the side surface of the blade body.

It is desirable to form the cutting edge portion by applying the adhesive containing the abrasive grains to the tip portion of the holder. This can reduce manufacturing costs.

It is desirable to form the cutting edge portion by applying the adhesive containing the abrasive grains to the tip portion of the holder while the tip portion of the holder faces vertically downward. As a result, the cutting edge can be sharpened.

The base end side of the holding body is coated with a coating member that repels the adhesive, and the adhesive containing abrasive grains is applied to the tip side of the coating member. It is desirable to form a cutting edge. As a result, the area to which the adhesive is applied can be limited to only the tip of the holder, and the area to which the adhesive is applied can be narrowed.

preparing a holder; applying an adhesive containing abrasive grains to the tip of the holder; removing the adhesive applied to the holder; A method for manufacturing a blade body for an optical fiber cutter, which is characterized by performing a step of forming, will be clarified. According to such a manufacturing method, the abrasive grains can be arranged only at the tip of the blade, and the area where the abrasive grains are arranged can be narrowed on the side surface of the blade.

A base end side of the holder is coated with a coating member, an adhesive containing abrasive grains is applied to the tip side of the coating member, and the coating member is coated after the adhesive is cured. It is desirable to form the cutting edge portion at the distal end portion of the holding body by removing the . This facilitates the work of removing the adhesive.

After applying the adhesive to the holding body, it is preferable to remove the adhesive applied to the holding body by scraping off a portion of the holding body that is closer to the base end than the distal end portion. As a result, the area where the abrasive grains are arranged on the side surface of the blade can be narrowed, and the cut surface of the optical fiber is less likely to come into contact with the side surface of the blade, so damage to the cut surface of the optical fiber can be suppressed.

After applying the adhesive to the holder and curing the adhesive, it is desirable to scrape off a portion of the holder closer to the proximal side than the distal end. However, after applying the adhesive to the holding body and before curing the adhesive, a portion of the holding body on the proximal side of the distal end portion may be scraped off.

The steps of preparing a holding body and forming a coating part covering the base end side of the tip part while forming a cutting edge part at the tip part of the holding body with an adhesive containing abrasive grains are performed. A method for manufacturing a blade body for an optical fiber cutter characterized by the above becomes clear. According to such a manufacturing method, the abrasive grains can be arranged only at the tip of the blade, and the area where the abrasive grains are arranged can be narrowed on the side surface of the blade.

It is desirable to form the coating portion by coating the base end side with a coating member after curing the adhesive. As a result, since the abrasive grains on the side surface of the holder are coated, damage to the cut surface of the optical fiber can be suppressed.

After applying an adhesive containing abrasive grains to the tip portion of the holder, the tip portion is turned up and heated to form a coat portion with the adhesive flowing from the tip portion to the base end side. It is desirable to As a result, the coated portion is composed of an adhesive that contains almost no abrasive grains, and the surface of the coated portion is smooth, so that damage to the cut surface of the optical fiber can be suppressed.

===About Fiber Cutter===
First, a fiber cutter for cutting an optical fiber will be described, and then a method for manufacturing a blade used for the fiber cutter (blade for optical fiber cutter) will be described.

FIG. 1 is a perspective view of the fiber cutter 100. FIG. FIG. 2 is an exploded perspective view of the fiber cutter 100. FIG. 3A to 3C are explanatory diagrams of the operation of the fiber cutter 100. FIG. 4A to 4C are schematic explanatory diagrams of the fiber cutter 100. FIG.

In the following description, each direction is defined as shown in FIG. That is, the direction parallel to the moving direction of the moving member 40 is defined as the "X-axis direction" or the "front-back direction", and the side along which the moving member 40 moves immediately after the optical fiber 1 is cut is defined as the "+X direction" or "forward", The opposite side (the holder 3 side when viewed from the moving member 40) is referred to as "-X direction" or "rear". Further, the direction perpendicular to the mounting surface 41B on which the end portion of the optical fiber 1 is mounted is defined as the "Z-axis direction" or the "vertical direction", and the side on which the optical fiber 1 is mounted as viewed from the mounting surface 41B is defined as the "Z-axis direction". +Z direction” or “up”, and the opposite side is called “−Z direction” or “down”. Further, the direction perpendicular to the X-axis direction (front-rear direction) and the Z-axis direction (vertical direction) is defined as the Y-axis direction, and the side of the rotating portion 45A viewed from the optical fiber 1 is defined as the "+Y direction" or "back", The opposite side is defined as "-Y direction" or "front side".

A fiber cutter 100 is a cutting device that cuts the optical fiber 1 . The fiber cutter 100 is a device that cuts the optical fiber 1 by forming an initial flaw in the optical fiber 1 with a blade 47 (blade) and growing the initial flaw to cleave the optical fiber 1 .

The fiber cutter 100 has a base member 10 and a moving member 40 . The fiber cutter 100 also has a latch portion 50 and a tension applying spring 60 .

The base member 10 has a holder mounting portion 11 , a guide portion 13 and an operating portion 15 .
The holder mounting portion 11 is a portion on which the holder 3 holding the optical fiber 1 is mounted. The holder mounting portion 11 is arranged on the rear side of the base member 10 .
The guide portion 13 is a portion that guides the moving member 40 so as to be movable in the front-rear direction. The guide portion 13 is formed on the front side of the base member 10 .

The operation part 15 is a part operated by the operator. The operating portion 15 is configured to be openable (rotatable) with respect to the main body of the base member 10 . By operating the operation unit 15 by the operator, the blade body 47 is brought closer to the optical fiber 1 to form an initial scratch on the optical fiber 1 .

The operating portion 15 has a rotating portion 15A, a housing portion 15B, and a latch releasing portion 15C.
The rotating portion 15A is a connecting portion that rotatably connects the operation portion 15 to the base member 10 . The accommodating portion 15B is a portion that accommodates the wound forming portion 46 inside. The accommodation portion 15B accommodates the wound forming portion 46 so as to be movable in the front-rear direction with respect to the operation portion 15 . The inner wall surface of the accommodating portion 15B (the facing surface facing the upper surface of the wound-forming portion 46) is a portion that presses the wound-forming portion 46. As shown in FIG.
The latch release portion 15C is a portion that releases the latched state of the latch portion 50. As shown in FIG. When the operator rotates the operation portion 15 in the closing direction, the latch release portion 15C releases the latch portion 50 from the latched state.

The moving member 40 is a member movable with respect to the base member 10 . The moving member 40 moves forward immediately after the optical fiber 1 is cut (see FIGS. 3C and 4C). The moving member 40 has a moving body 41 , a gripping member 45 , a wound forming portion 46 and a bending portion 48 .

The moving body 41 is a part that constitutes the main body of the moving member 40 . The moving body 41 can move in the front-rear direction while being guided by the guide portion 13 of the base member 10 . An end of a tension applying spring 60 is connected to the movable body 41 , and the force of the tension applying spring 60 causes the movable body 41 to move relative to the base member 10 . Moreover, the grasping member 45 and the scar forming portion 46 are provided so as to be independently rotatable with respect to the moving body 41 .

The moving body 41 has a case accommodating portion 41A, a mounting surface 41B, and an engaging hole 41C.
The case accommodating portion 41A is a portion that accommodates the waste material case 5 . The waste material case 5 is a case for storing the cut ends of the optical fibers 1 .
The mounting surface 41B is a surface on which the end of the optical fiber 1 is mounted. The mounting surface 41B may have a V-groove formed thereon, or may have a flat surface without a V-groove formed thereon. The optical fiber 1 is gripped by being sandwiched between the mounting surface 41B and the gripping member 45 (specifically, the clamp portion 45B). Here, the placement surface 41B is a surface parallel to the XY plane (a surface perpendicular to the Z-axis direction).
The engaging hole 41C is a portion for locking the locking portion 45C of the gripping member 45. As shown in FIG. By engaging the engagement portion 45C with the engagement hole 41C, the grip member 45 is fixed in a closed state, and the optical fiber 1 is held between the mounting surface 41B and the clamp portion 45B.

The gripping member 45 is a member that grips the end of the optical fiber 1 . The grip member 45 is configured to be openable and closable (rotatable) with respect to the moving body 41 . The gripping member 45 is arranged on the front side of the blade body 47 . For this reason, the gripping member 45 grips the end portion of the optical fiber 1 (the portion that becomes waste after cutting) on the front side of the cutting position of the optical fiber 1 . The gripping member 45 has a rotating portion 45A, a clamping portion 45B, and a locking portion 45C.
45 A of rotation parts are connection parts which connect the holding member 45 with respect to the moving body 41 so that rotation is possible. The clamp part 45B is a part that comes into contact with the end of the optical fiber 1 mounted on the mounting surface 41B and presses the optical fiber 1 against the mounting surface 41B. That is, the optical fiber 1 is clamped vertically between the mounting surface 41B and the clamp portion 45B. The engaging portion 45C is a portion that is engaged with the engaging hole 41C of the moving body 41, and is a portion that fixes the gripping member 45 in a closed state. By locking the engaging portion 45C to the engaging hole 41C of the moving body 41 and fixing the gripping member 45 in a closed state, the optical fiber 1 is held between the mounting surface 41B and the clamp portion 45B. It will be.

The scratch forming portion 46 is a portion for forming an initial scratch on the optical fiber 1 . The wound forming part 46 is configured to be openable (rotatable) with respect to the moving body 41 . The wound forming portion 46 has a rotating portion 46A and a blade body 47 . 46 A of rotation parts are connection parts which connect the wound formation part 46 with respect to the moving body 41 so that rotation is possible. The blade body 47 is a portion (blade) that forms an initial scratch on the optical fiber 1 . The upper surface of the wound forming portion 46 is a portion pressed by the inner wall surface of the housing portion 15B of the operation portion 15 . When the operator rotates the operating portion 15 in the closing direction, the wound forming portion 46 is pressed in the closing direction by the inner wall surface of the housing portion 15B, and the wound forming portion 46 also rotates in the closing direction. As a result, the blade 47 of the scratch forming portion 46 forms an initial scratch on the optical fiber 1 . A method for manufacturing the blade body 47 will be described later.

The bending portion 48 is a portion that applies bending stress to the optical fiber 1 . By forming an initial scratch on the optical fiber 1 while applying a bending stress to the optical fiber 1, the cut surface of the optical fiber 1 can be inclined (inclined with respect to a plane perpendicular to the optical axis of the optical fiber 1). . The bent portion 48 (more specifically, the bottom portion of the V-shaped recess) is arranged above the mounting surface 41B and supports the optical fiber 1 above the mounting surface 41B. As a result, as shown in FIG. 5A, when the optical fiber 1 is gripped by the gripping member 45 (clamping portion 45B), the optical fiber 1 is placed upward as it is closer to the bending portion 48 and the clamping portion. 45B to be bent in an S shape.

The latch portion 50 is a portion that latches the base member 10 and the moving member 40 . The latch portion 50 has a base side latch portion 51 and a moving side latch portion 54 . The base-side latch portion 51 is a cantilever-like portion provided on the base member 10 . The base-side latch portion 51 contacts the latch release portion 15C of the operation portion 15 and is elastically deformed. As a result, the base side latch portion 51 is disengaged from the moving side latch portion 54 and the latched state is released. The moving-side latch portion 54 is a portion provided on the moving member 40 and is a portion for hooking the end portion of the base-side latch portion 51 .

The tension applying spring 60 is a member (tension applying part) that applies force between the base member 10 and the moving member 40 . A tensioning spring 60 is positioned between the base member 10 and the moving member 40 . One end (front end) of the tension applying spring 60 is connected to the base member 10 and the other end is connected to the moving member 40 . When the latch portion 50 is in the latched state (when the base-side latch portion 51 and the moving-side latch portion 54 are in the latched state), a tensile force is applied to the tension applying spring 60 .

Next, the basic operation of the fiber cutter 100 when cutting the optical fiber 1 will be described.

When the latch portion 50 is in the released state, the operator moves the moving member 40 rearward (toward the holder 3) to bring it into the latched state. In the latched state, the base member 10 and the moving member 40 are fixed with the tensile force applied to the tension applying spring 60 . Further, in the latched state, the scratch forming portion 46 is accommodated inside the accommodating portion 15B of the operation portion 15 (the inner wall surface of the accommodating portion 15B and the upper surface of the scratch forming portion 46 face each other). .

The operator sets the holder 3 on the holder mounting portion 11 of the base member 10 . The holder 3 holds the optical fiber 1 to be cut. An optical fiber 1 extends from the front side of the holder 3, and the end of the optical fiber 1 is previously uncoated. When the holder 3 is set on the holder mounting portion 11, the operator inserts the end portion of the optical fiber 1 into the waste material case 5 while placing the optical fiber 1 on the mounting surface 41B. do. As a result, when the operator sets the holder 3 on the holder mounting portion 11 , the optical fiber 1 is stretched between the holder 3 and the waste material case 5 .

Next, as shown in FIGS. 3A and 4A, the operator closes the gripping member 45 and clamps the optical fiber 1 between the placement surface 41B and the gripping member 45 (specifically, the clamp portion 45B). , the optical fiber 1 is gripped. At this time, in this embodiment, bending stress is applied to the optical fiber 1 by the bending portion 48 (see FIG. 5A).

After gripping the optical fiber 1 by the gripping member 45, the operator closes the operating portion 15 (and the wound forming portion 46) as shown in FIGS. 3B and 4B. When the operating portion 15 is rotated in the closing direction, the scratch forming portion 46 is also rotated in the closing direction together with the operating portion 15 , and the blade body 47 of the scratch forming portion 46 moves toward the optical fiber 1 .

As shown in FIG. 4B , when the operation portion 15 is rotated in the closing direction, the latch release portion 15C of the operation portion 15 contacts the base side latch portion 51 . Further, when the operating portion 15 is rotated in the closing direction, the base side latch portion 51 is disengaged from the moving side latch portion 54 to release the latched state. When the latched state is released, tension is applied to the optical fiber 1 by applying the force of the tension applying spring 60 between the base member 10 and the moving member 40 . Before the optical fiber 1 is cut, tension acts on the optical fiber 1, so the moving member 40 does not move at this stage.

Further, when the operating portion 15 is rotated in the closing direction after the latched state is released, the blade body 47 of the scratch forming portion 46 contacts the optical fiber 1 and an initial scratch is formed on the optical fiber 1 . When an initial flaw is formed in the optical fiber 1 under tension, the initial flaw grows and the optical fiber 1 is cleaved, thereby cutting the optical fiber 1 . When the optical fiber 1 is cut, the moving member 40 is moved forward by the force of the tensioning spring 60, as shown in FIGS. 3C and 4C. In this embodiment, since the bending stress is applied to the optical fiber 1, the cut plane (cleavage plane) of the optical fiber 1 is inclined with respect to the plane perpendicular to the optical axis of the optical fiber 1. .

FIG. 5A is an explanatory diagram of how the blade 47 forms an initial scratch on the optical fiber 1 to which bending stress is applied.

When the optical fiber 1 is cleaved by growing an initial scratch, it is desirable to form the initial scratch at a portion where a large tensile force is applied. When bending stress is applied to the optical fiber 1, the convex portion of the S-shaped curved optical fiber 1 (the portion on the side opposite to the center of curvature of the optical fiber 1) is A large tensile force is acting inside. Therefore, in this embodiment, the blade body 47 forms an initial scratch on the convex portion of the optical fiber 1 curved in an S shape. Here, the blade body 47 forms an initial scratch on the upper portion of the optical fiber 1 at a position near the bent portion 48 between the bent portion 48 and the clamp portion 42B.

On the other hand, when the optical fiber 1 to which the bending stress is applied is cut, the elastic deformation of the optical fiber 1 returns after cutting as indicated by the dotted line in the figure. When the blade body 47 forms an initial scratch on the convex portion of the optical fiber 1, when the elastic deformation of the optical fiber 1 returns, the cut surface of the optical fiber 1 (the end face of the optical fiber 1 on the holder 3 side) is replaced by the blade body. It will jump up towards 47. As a result, the cut surface of the optical fiber 1 comes into contact with the side surface of the blade 47 .

FIG. 5B is an explanatory diagram of the blade body 47 of the reference example. The shaded portion in the drawing indicates the region where abrasive grains are arranged on the surface. For example, when a polishing sheet is attached to the base material (holding body) of the blade body 47, abrasive grains are arranged in a wide area on the side surface like the blade body 47 of the reference example in the figure. If abrasive grains are arranged over a wide area on the side surface of the blade as in the reference example, the cut surface of the optical fiber immediately after cutting will come into contact with the abrasive grains on the side surface of the blade. As a result, the cleaved cut surface (mirror cut surface) is damaged by the abrasive grains. In this way, the inventors of the present application have found that when the cutting surface is inclined by applying a bending stress to the optical fiber 1, if abrasive grains are arranged in a wide area on the side surface of the blade body 47, the cutting surface will be damaged. discovered to do Further, the inventors of the present application discovered that narrowing the area in which the abrasive grains are arranged can suppress damage to the cut surface.

In this embodiment, the area where the abrasive grains are arranged on the side surface of the blade body 47 is suppressed by the manufacturing method of the blade body 47 described below.

=== Manufacturing method of blade 47 ====
<First Embodiment>
FIG. 6A is an explanatory diagram of a method for manufacturing the blade body 47 of the first embodiment.

The blade body 47 has a cutting edge portion 471 and a holder 472 (see the right diagram in FIG. 6A).
The cutting edge portion 471 is a portion that constitutes the tip of the blade body 47 . The cutting edge portion 471 is formed by curing an adhesive containing abrasive grains. Abrasive grains are, for example, diamond powder (however, abrasive grains are not limited to diamond powder). The adhesive is, for example, a thermosetting resin (however, the adhesive is not limited to a thermosetting resin). The cutting edge portion 471 has a cutting line at the tip, and abrasive grains are partially exposed on the cutting line, and initial scratches are formed in the optical fiber 1 when the abrasive grains come into contact with the optical fiber 1. It will be.
The holding body 472 is a member that constitutes the base material of the blade body 47 and is a member that provides the cutting edge portion 471 . Here, the holder 472 is made up of a molded part made of plastic. The single holder 472 does not contain abrasive grains.

As shown in FIG. 6A, the retainer 472 of the first embodiment has a flattened tip portion. In other words, in the first embodiment, the holder 472 having a trapezoidal cross section is prepared. Thus, in the first embodiment, the tip of the holder 472 is formed with a flat end face. This end surface of the holder 472 serves as an attachment surface (adhesive surface) for attaching the cutting edge portion 471 .

Also, in the first embodiment, a mold 71 having a V-groove is prepared. Then, in the first embodiment, an adhesive 471A containing abrasive grains is injected into the V-groove of the mold 71, the adhesive 471A is heated to harden the adhesive 471A, and the cutting edge portion 471 is molded.

By the way, it is also possible to manufacture the blade body 47 by bonding the molded blade tip portion 471 to the tip of the holder 472 after molding the blade tip portion 471 . However, in this case, the step of curing the adhesive 471A forming the cutting edge portion 471 (molding step) and the step of bonding the cutting edge portion 471 and the holder 472 (attaching step) must be performed separately. It takes longer to manufacture.
Therefore, in the first embodiment, as shown in FIG. 6A, after the adhesive 471A containing abrasive grains is injected into the V-groove of the mold 71, and before the adhesive 471A injected into the V-groove is cured, holding The end face of the tip of the body 472 is placed in the V-groove of the mold 71, and the end face of the tip of the holder 472 is brought into contact with the adhesive 471A injected into the V-groove. Then, the adhesive 471A is heated and hardened while the end surface of the tip portion of the holder 472 is brought into contact with the adhesive 471A injected into the V-groove, and the cutting edge portion 471 is fixed to the tip portion of the holder 472 . Accordingly, forming the cutting edge portion 471 by curing the adhesive and holding the cutting edge portion 471 on the holder 472 can be performed simultaneously in one step, thereby shortening the manufacturing time.

According to the method for manufacturing the blade body 47 of the first embodiment, the steps of preparing the holding body 472 on which the blade edge portion 471 is provided, and and a step of forming the tip portion. As a result, the abrasive grains can be arranged only at the tip portion of the blade body 47, and the area where the abrasive grains are arranged on the side surface of the blade body 47 can be narrowed. If such a blade 47 is used, when bending stress is applied to the optical fiber 1 to incline the cut surface, the elastic deformation of the optical fiber 1 after cutting returns and the cut surface of the optical fiber 1 becomes the blade. Since the cut surface of the optical fiber 1 easily contacts the holder 472 even if it contacts the side surface of the optical fiber 47, damage to the cut surface can be suppressed.

Further, according to the method for manufacturing the blade body 47 of the first embodiment, the blade tip portion 471 is formed by molding the adhesive 471A containing abrasive grains. Thereby, a sharp cutting edge portion 471 can be formed. In addition, compared to the case where the blade body is manufactured by attaching an abrasive sheet, for example, it becomes easier to arrange the abrasive grains only at the tip of the blade body 47, and the area where the abrasive grains are arranged on the side surface of the blade body 47 is reduced. Easier to narrow.

Further, according to the method for manufacturing the blade body 47 of the first embodiment, when the adhesive 471A containing abrasive grains is molded, the tip of the holder 472 is placed inside the mold 71 (in this case, inside the V-groove). ), and the cutting edge portion 471 is fixed to the tip portion of the holder 472 during molding. Thereby, the manufacturing process of the blade body 47 can be simplified.

<Second embodiment>
FIG. 6B is an explanatory diagram of a method for manufacturing the blade body 47 of the second embodiment.

Also in the second embodiment, a mold 71 having a V-groove is prepared. Then, in the second embodiment, an adhesive 471A containing abrasive grains is injected into the V-groove of the mold 71, and the cutting edge portion 471 is molded. Note that the V-groove of the second embodiment is allowed to be larger than the V-groove of the first embodiment. In other words, it is permissible for the cutting edge portion 471 molded in the second embodiment to be larger than the cutting edge portion 471 in the first embodiment.

Next, as shown in FIG. 6B, a holder 472 having an attachment portion 472A at the tip is prepared, and the cutting edge portion 471 is attached to the attachment portion 472A of the holder 472. Next, as shown in FIG. The mounting portion 472A is a portion that clamps both side surfaces of the cutting edge portion 471 from the outside. The mounting portion 472A has not only the function of mounting the cutting edge portion 471, but also the function of covering the side surface of the cutting edge portion 471 (function of the coating portion). The tip portion (blade line) of the cutting edge portion 471 is exposed from the attachment portion 472A, and the abrasive grains of the cutting edge portion 471 can form an initial scratch on the optical fiber 1 .

According to the method for manufacturing the blade body 47 of the second embodiment, as in the first embodiment, the step of preparing the holding body 472 on which the cutting edge portion 471 is provided and the adhesive 471A containing abrasive grains are formed. A step of forming the cutting edge portion 471 at the tip portion of the holder 472 is performed. As a result, the abrasive grains can be arranged only at the tip portion of the blade body 47, and the area where the abrasive grains are arranged on the side surface of the blade body 47 can be narrowed.

Further, according to the method for manufacturing the blade body 47 of the second embodiment described above, the cutting edge portion 471 is formed by molding the adhesive 471A containing abrasive grains, as in the first embodiment. . Thereby, a sharp cutting edge portion 471 can be formed. In addition, this makes it easier to dispose the abrasive grains only at the tip of the blade body 47 compared to the case where the blade body is manufactured by attaching an abrasive sheet, for example, and the abrasive grains are disposed on the side surface of the blade body 47. It becomes easier to narrow the area to be covered.

Further, according to the method for manufacturing the blade body 47 of the second embodiment, after the blade tip portion 471 is molded, the blade tip portion 471 is attached to the holder 472 by the attachment portion 472A that clamps the side surface of the blade tip portion 471. there is As a result, both side surfaces of the cutting edge portion 471 are covered with the mounting portions 472A of the holder 472, and the abrasive grains on the side surfaces of the cutting edge portion 471 are covered with the mounting portions 472A. You can narrow the area that is covered.

<Third Embodiment>
FIG. 7A is an explanatory diagram of a method for manufacturing the blade body 47 of the third embodiment.

A holding body 472 of the third embodiment has a flattened end portion, as in the first embodiment (see FIG. 6A). That is, also in the third embodiment, the holder 472 having a trapezoidal cross section is prepared. In the third embodiment, the flat end surface of the tip portion of the holder 472 serves as a surface ((applied surface)) to which the adhesive 471A constituting the cutting edge portion 471 is applied.

Further, in the third embodiment, a dispenser (injection device) filled with an adhesive 471A containing abrasive grains is prepared. In the third embodiment, the end face of the holder 472 faces vertically downward, and an adhesive 471A containing abrasive grains is applied to the end face of the holder 472 . Note that the method of applying the adhesive 471A is not limited to using a dispenser as long as the method is capable of applying the adhesive 471A to the tip portion of the holder 472 . After applying the adhesive 471A, the adhesive 471A is heated to harden the adhesive 471A, thereby forming the cutting edge portion 471 at the tip portion of the holder 472. As shown in FIG.

According to the method for manufacturing the blade body 47 of the third embodiment, as in the above-described embodiment, the step of preparing the holding body 472 on which the cutting edge portion 471 is provided and the adhesive 471A containing abrasive grains are formed. A step of forming the cutting edge portion 471 at the tip portion of the holder 472 is performed. As a result, the abrasive grains can be arranged only at the tip portion of the blade body 47, and the area where the abrasive grains are arranged on the side surface of the blade body 47 can be narrowed.

Further, in the third embodiment, the cutting edge portion 471 is formed by applying an adhesive 471A containing abrasive grains to the tip portion of the holder 472 . As a result, the third embodiment does not require a mold (mold) as in the first and second embodiments, so that the manufacturing cost can be reduced.

Further, in the third embodiment, the adhesive 471A is applied to the tip portion of the holder 472 while the end surface of the holder 472 faces downward in the vertical direction. As a result, the cutting edge 471 can be formed sharper than when the adhesive 471A is applied while the tip of the holder 472 faces vertically upward.

<Fourth Embodiment>
In the above-described third embodiment, the flat end face was formed at the tip of the holder 472 . However, the end face of the holder 472 does not have to be flat. Further, in the above-described third embodiment, when the adhesive 471A is applied to the tip of the holder 472, the tip of the holder 472 is directed downward in the vertical direction. However, it is also possible to apply the adhesive 471A to the tip of the holder 472 while the tip of the holder 472 faces vertically upward.

FIG. 7B is an explanatory diagram of a method for manufacturing the blade body 47 of the fourth embodiment.

Also in the fourth embodiment, a holder 472 on which a cutting edge portion 471 is provided is prepared. In the fourth embodiment, the tip of the holder 472 is not formed with a flat end surface.

In the fourth embodiment, the base end side of the holder 472 (the root side opposite to the tip end) is covered with the coating member 72 . As a result, while the side surface of the holder 472 is covered with the coating member 72 , the holder 472 is exposed at the tip of the holder 472 , and the tip of the holder 472 is surrounded by the coat member 72 . Become.

The coating member 72 of the fourth embodiment is a member that repels the adhesive 471A (the adhesive 471A containing abrasive grains). Here, grease is used as the coating member 72 . However, the coating member 72 of the fourth embodiment is not limited to grease. For example, although the coating member 72 of the fourth embodiment is liquid (grease), it may be a solid member (for example, sheet-like or tape-like).

Also in the fourth embodiment, a dispenser (injection device) filled with an adhesive 471A containing abrasive grains is prepared. In the fourth embodiment, the adhesive 471A is applied to the tip of the holding body 472 while the tip of the holding body 472 faces upward in the vertical direction. Note that the method of applying the adhesive 471A is not limited to using a dispenser as long as the method is capable of applying the adhesive 471A to the tip portion of the holder 472 .

By the way, in the fourth embodiment, a flat end surface is not formed at the tip of the holder 472 . Therefore, when the adhesive 471A is applied to the tip of the holding body 472 while the tip of the holding body 472 faces vertically upward, the adhesive 471A easily flows down from the tip of the holding body 472. FIG. However, in the fourth embodiment, since the coating member 72 is coated so as to surround the tip of the holder 472 (the portion to which the adhesive 471A is applied), the adhesive 471A flows down from the tip of the holder 472. Since this can be prevented, the range to which the adhesive 471A is applied can be limited to only the tip of the holder 472, and the area to which the adhesive 471A is applied can be narrowed.

After applying the adhesive 471A, the adhesive 471A is heated to harden the adhesive 471A, thereby forming the cutting edge portion 471 at the tip portion of the holder 472. As shown in FIG. After the cutting edge portion 471 is formed, the coating member 72 (grease) on the side surface of the holder 472 is wiped off, thereby completing the manufacture of the blade.

According to the method for manufacturing the blade body 47 of the fourth embodiment, as in the above-described embodiment, the step of preparing the holding body 472 on which the blade tip portion 471 is provided and the adhesive 471A containing abrasive grains are formed. A step of forming the cutting edge portion 471 at the tip portion of the holder 472 is performed. As a result, the abrasive grains can be arranged only at the tip portion of the blade body 47, and the area where the abrasive grains are arranged on the side surface of the blade body 47 can be narrowed.

Further, in the fourth embodiment, similarly to the third embodiment, the cutting edge portion 471 is formed by applying an adhesive 471A containing abrasive grains to the tip portion of the holder 472 . Thus, in the fourth embodiment, unlike the first and second embodiments, the mold is not required, so the manufacturing cost can be reduced.

In the fourth embodiment, the base end side of the holder 472 is covered with the coating member 72, and the adhesive 471A (abrasive-containing adhesive 471A) is applied to the tip side of the coating member 72. is applied to form the cutting edge portion 471 . In the fourth embodiment, since the adhesive 471A is repelled by the coating member 72, the range to which the adhesive 471A is applied can be limited only to the tip of the holder 472, and the area to which the adhesive 471A is applied can be limited to can be narrowed. As a result, the abrasive grains can be arranged only at the tip portion of the blade body 47, and the area where the abrasive grains are arranged on the side surface of the blade body 47 can be narrowed. In addition, in the fourth embodiment, since the coating member 72 repels the adhesive 471A, the droplets of the adhesive 471A are formed into a raised shape, so there is an advantage that the cutting edge portion 471 can be formed sharp.

<Fifth Embodiment>
FIG. 8A is an explanatory diagram of a method for manufacturing the blade body 47 of the fifth embodiment.

Also in the fifth embodiment, a holder 472 having a cutting edge portion 471 is prepared. In the fifth embodiment, the tip of the holder 472 is not formed with a flat end surface.

In the fifth embodiment, the base end side of the holder 472 (the root side opposite to the tip end) is covered with the coating member 73 . As a result, while the side surface of the holder 472 is covered with the coating member 73 , the holder 472 is exposed at the tip of the holder 472 .

Unlike the coating member 73 (grease) of the fourth embodiment, the coating member 73 of the fifth embodiment may not be a member that repels the adhesive 471A (the adhesive 471A containing abrasive grains). It is a member whose surface can be coated with an adhesive 471A. Here, the tape member is used as the coating member 73 and attached to the side surface of the holder 472 . In addition, as will be described later, the coating member 73 of the fifth embodiment is a member that can be removed from the holder 472 .

Also in the fifth embodiment, an adhesive 471A containing abrasive grains is applied to the tip portion of the holder 472. As shown in FIG. Also in the fifth embodiment, the adhesive agent 471A containing abrasive grains is applied to the tip portion side of the coating member 73 . However, in the fifth embodiment, unlike the third and fourth embodiments described above, the adhesive 471A may be applied not only to the tip of the holder 472 but also to the coating member 73 . Thus, in the fifth embodiment, even if the area to which the adhesive 471A is applied is wider than in the above-described third and fourth embodiments, it is permissible. Therefore, in the fifth embodiment, as a method of applying the adhesive 471A to the tip portion of the holder 472, it is possible to widely adopt a method other than the method using a dispenser.

After applying the adhesive 471A, the adhesive 471A is heated to cure the adhesive 471A. In this embodiment, the adhesive 471A applied on the tip of the holder 472 and the coating member 73 is cured.

In the fifth embodiment, the coating member 73 is removed from the holder 472 after the adhesive 471A is cured. At this time, the adhesive 471A cured on the coating member 73 is also removed together with the coating member 73. As shown in FIG. On the other hand, the adhesive 471A (adhesive 471A containing abrasive grains) hardened on the tip portion of the holder 472 remains without being removed, forming the cutting edge portion 471 .

In FIG. 8A, both side surfaces of the holder 472 are pre-coated with the coating member 73, and the both side coating members 73 are removed from the holder 472 after the adhesive 471A is cured. Side adhesive 471A has been removed. However, the adhesive 471A on one side of the holder 472 may be removed and the adhesive 471A may remain on the other side. It is sufficient that the adhesive 471A on the rear side (holder side) side surface of the holder 472 in the fiber cutter is removed.

According to the method for manufacturing the blade body 47 of the fifth embodiment, the steps of preparing the holder 472 on which the blade edge portion 471 is provided and the steps of applying the adhesive 471A containing abrasive grains to the tip portion of the holder 472 and a step of removing the adhesive 471A applied to the holder 472 and forming the cutting edge portion 471 at the tip portion. As a result, the abrasive grains can be arranged only at the tip portion of the blade body 47, and the area where the abrasive grains are arranged on the side surface of the blade body 47 can be narrowed. In the fifth embodiment, unlike the above-described embodiments, there is a step of removing the adhesive 471A applied to the holder 472, so even if the area to which the adhesive 471A is applied is widened, it is allowed. , it becomes easier to apply the adhesive 471A to the tip portion of the holder 472 .

Further, in the above-described fifth embodiment, the base end side of the holding body 472 is covered with the coating member 73 before the adhesive 471A is applied, and the coating member 73 is removed after the adhesive 471A is cured. A cutting edge portion 471 is formed at the tip portion of 472 . This facilitates the work of removing the adhesive 471A.

<Sixth Embodiment>
FIG. 8B is an explanatory diagram of a method for manufacturing the blade body 47 of the sixth embodiment.

Also in the sixth embodiment, a holder 472 on which a cutting edge portion 471 is provided is prepared in the same manner as in the fifth embodiment. Also in the sixth embodiment, an adhesive 471A containing abrasive grains is applied to the tip portion of the holder 472 in the same manner as in the fifth embodiment. However, in the sixth embodiment, unlike the fifth embodiment, the holder 472 is not coated with the coating member 73 . Therefore, in the sixth embodiment, the adhesive 471A is applied to the distal end portion of the holder 472 and the side surface on the base end side. Also in the sixth embodiment, as in the fifth embodiment, even if the area to which the adhesive 471A is applied is wide, it is allowed.

After applying the adhesive 471A, the adhesive 471A is heated to cure the adhesive 471A. In this embodiment, the adhesive 471A applied to the distal end portion and the base end side surface of the holder 472 is cured.

In the sixth embodiment, after curing the adhesive 471A, while leaving the adhesive 471A at the tip of the holder 472, the portion of the holder 472 closer to the proximal side than the tip is scraped off with a tool. The adhesive 471A applied to the side surface of 472 is removed. Here, the adhesive 471A applied to the side surface of the holder 472 is removed by cutting the base end side portion of the holder 472 with a knife. The adhesive 471A (adhesive 471A containing abrasive grains) remaining on the tip portion of the holder 472 forms the cutting edge portion 471 .

In FIG. 8B, both side surfaces of the holder 472 are scraped off together with the adhesive 471A by a tool. However, one side surface of the holder 472 may be scraped off together with the adhesive 471A with a tool, and the adhesive 471A may remain on the other side surface. Note that the rear side (holder side) side surface of the holder 472 in the fiber cutter 100 may be scraped off together with the adhesive 471A by a tool (see FIG. 9).

According to the method for manufacturing the blade body 47 of the sixth embodiment, as in the fifth embodiment, the step of preparing the holding body 472 on which the cutting edge portion 471 is provided, and the step of and a step of removing the adhesive 471A applied to the holder 472 and forming the cutting edge 471 at the tip. As a result, the abrasive grains can be arranged only at the tip portion of the blade body 47, and the area where the abrasive grains are arranged on the side surface of the blade body 47 can be narrowed. In the sixth embodiment, as in the fifth embodiment described above, there is a step of removing the adhesive 471A applied to the holder 472, so even if the area to which the adhesive 471A is applied is widened, it is acceptable. This makes it easier to apply the adhesive 471A to the tip of the holder 472. As shown in FIG.

FIG. 9 is an explanatory view showing how the blade body 47 manufactured by the manufacturing method of the sixth embodiment is used to cut the optical fiber 1 to which the bending stress is applied.

As already explained, when the optical fiber 1 to which the bending stress is applied is cut, the elastic deformation of the optical fiber 1 returns after cutting as indicated by the dotted line in the figure. When the elastic deformation of the optical fiber 1 returns, the cut surface of the optical fiber 1 (the end surface of the optical fiber 1 on the holder 3 side) springs up toward the blade body 47 .

In the blade 47 manufactured by the manufacturing method of the sixth embodiment, the rear side (holder side) side is scraped off together with the adhesive 471A by a tool, so that the side of the blade 47 is recessed. As a result, the cut surface of the optical fiber 1 is less likely to come into contact with the side surface of the blade body 47, so damage to the cut surface of the optical fiber 1 can be suppressed. Even if the cut surface of the optical fiber 1 contacts the side surface of the blade 47, damage to the cut surface of the optical fiber 1 can be suppressed because the adhesive 471A on the side surface of the blade 47 is removed.

<Seventh embodiment>
In the above embodiment, the adhesive 471A is made of a thermosetting resin, and heating is required when curing the adhesive 471A. Further, in the above embodiment, the adhesive 471A was assumed to have a relatively low viscosity. However, the adhesive 471A may not be a thermosetting resin, and may have a relatively high viscosity.

FIG. 8C is an explanatory diagram of a method for manufacturing the blade body 47 of the seventh embodiment. The adhesive 471A of the seventh embodiment is composed of an adhesive PPX (manufactured by Cemedine Co., Ltd.), which cures without heating and has a relatively high viscosity.

Also in the seventh embodiment, a holder 472 on which a cutting edge portion 471 is provided is prepared in the same manner as in the fifth and sixth embodiments. Also in the seventh embodiment, an adhesive 471A containing abrasive grains is applied to the tip portion of the holder 472, as in the fifth and sixth embodiments. Also in the seventh embodiment, the holder 472 is not coated with the coating member 73, as in the sixth embodiment. Also in the seventh embodiment, as in the sixth embodiment, even if the area to which the adhesive 471A is applied is wide, it is allowed.

In the seventh embodiment, without the step of heating the adhesive 471A, while leaving the adhesive 471A at the tip of the holder 472, the portion of the holder 472 closer to the proximal side than the tip is scraped off with a tool. By doing so, the adhesive 471A applied to the side surface of the holder 472 is removed. The adhesive 471A (adhesive 471A containing abrasive grains) remaining on the tip portion of the holder 472 forms the cutting edge portion 471 . In the seventh embodiment, since the viscosity of the adhesive 471A is relatively high, the portion of the holder 472 closer to the proximal side than the distal end of the holder 472 is scraped off with a tool before the adhesive 471A is cured. It is possible to remove the adhesive 471A applied to the side surface of the .

According to the method for manufacturing the blade body 47 of the seventh embodiment, as in the fifth and sixth embodiments, the step of preparing the holding body 472 on which the cutting edge portion 471 is provided and the step of preparing the tip end portion of the holding body 472 and a step of removing the adhesive 471A applied to the holding member 472 and forming a cutting edge portion 471 on the tip portion. As a result, the abrasive grains can be arranged only at the tip portion of the blade body 47, and the area where the abrasive grains are arranged on the side surface of the blade body 47 can be narrowed. In the sixth embodiment, as in the fifth embodiment described above, there is a step of removing the adhesive 471A applied to the holder 472, so even if the area to which the adhesive 471A is applied is widened, it is acceptable. This makes it easier to apply the adhesive 471A to the tip of the holder 472. As shown in FIG.

Further, according to the method for manufacturing the blade body 47 of the seventh embodiment, similarly to the sixth embodiment, after the adhesive 471A is applied to the holding body 472, the base end side of the holding body 472 is more than the distal end portion. The adhesive 471A applied to the side surface of the holder 472 is removed by scraping off the portion of . This makes it difficult for the cut surface of the optical fiber 1 to come into contact with the side surface of the blade body 47 , so damage to the cut surface of the optical fiber 1 can be suppressed.

Further, according to the method for manufacturing the blade body 47 of the seventh embodiment, after the adhesive 471A is applied to the holding body 472 and before the adhesive 471A is cured, the base end of the holding body 472 is more inclined than the distal end. The adhesive 471A applied to the side surface of the holder 472 is removed by scraping off the side portion. As a result, the time from application of the adhesive 471A to removal of the adhesive 471A can be shortened.

<Eighth embodiment>
FIG. 10A is an explanatory diagram of a method for manufacturing the blade body 47 of the eighth embodiment.

Also in the eighth embodiment, a holder 472 is prepared in the same manner as in the fifth embodiment. Also in the eighth embodiment, similarly to the fifth embodiment described above, an adhesive 471A containing abrasive grains is applied to the tip of the holder 472 . However, in the eighth embodiment, unlike the fifth embodiment, the holding body 472 is not coated with the coating member 73 at the stage of applying the adhesive 471A to the holding body 472 . For this reason, in the eighth embodiment, the adhesive 471A is applied to the distal end portion of the holder 472 and the side surface on the base end side. Also in the eighth embodiment, as in the fifth embodiment, even if the area to which the adhesive 471A is applied is wide, it is allowed.

After applying the adhesive 471A, the adhesive 471A is heated to cure the adhesive 471A. In this embodiment, the adhesive 471A applied to the distal end portion and the base end side surface of the holder 472 is cured.

In the eighth embodiment, after the adhesive 471A is cured, the base end side of the holder 472 (the base side opposite to the tip end) is covered with the coating member 74 . In the eighth embodiment, the adhesive 471A applied to the side surface of the holder 472 remains without being removed. Since the side surface of the holding body 472 to which the adhesive 471A is applied is covered with the coating member 74, the abrasive grains arranged on the side surface of the holding body 472 are coated with the coating member 74. The adhesive 471A applied to the tip of the holder 472 is not covered with the coating member 74 and is exposed. The adhesive 471A applied to the tip of the holder 472 constitutes the cutting edge 471 of the blade 47. As shown in FIG.

Here, the tape member is used as the coating member 74 and attached to the side surface of the holder 472 (the side surface to which the adhesive 471A is applied). However, the coating member 74 is not limited to the tape member. For example, an adhesive 471A that does not contain abrasive grains is used as the coating member 74, and the base end side (root side opposite to the tip portion) of the holding body 472 is coated with the adhesive 471A that does not contain abrasive grains. You can Thus, the coating member 74 of the eighth embodiment is not limited to a solid member, and may be a liquid member. Unlike the coating member 74 of the fifth embodiment, the coating member 74 of the eighth embodiment does not have to be removable from the holder 472 .

According to the method for manufacturing the blade body 47 of the eighth embodiment, while forming the cutting edge portion 471 at the tip portion of the holder 472 by the step of preparing the holder 472 and the adhesive 471A containing abrasive grains, forming a coat portion (coated portion) that covers the base end side of the holder 472 rather than the tip end portion thereof. As a result, the abrasive grains can be arranged only at the tip portion of the blade body 47, and the area where the abrasive grains are arranged on the side surface of the blade body 47 can be narrowed. In the eighth embodiment, unlike the fifth to seventh embodiments described above, there is no step of removing the adhesive 471A applied to the holder 472, so the manufacturing process can be simplified.

Further, according to the method for manufacturing the blade body 47 of the eighth embodiment, after the adhesive 471A is cured, the base end side of the holder 472 is coated with the coating member 74 (a tape member, the adhesive 471A that does not contain abrasive grains, etc.). ) to form a coated portion (coated portion). As a result, the abrasive grains on the side surface of the holder 472 are coated, so even if the cut surface of the optical fiber 1 comes into contact with the side surface of the blade body 47, damage to the cut surface of the optical fiber 1 can be suppressed.

<Ninth Embodiment>
FIG. 10B is an explanatory diagram of a method for manufacturing the blade body 47 of the ninth embodiment.

Also in the ninth embodiment, a holder 472 is prepared. Further, in the ninth embodiment, a container 75 containing an adhesive (here, an adhesive 471B containing no abrasive grains) is prepared. Then, the tip of the holder 472 is directed downward in the vertical direction, and the tip of the holder 472 is brought into contact with the liquid surface of the adhesive 471B in the container 75 to apply the adhesive 471B to the tip of the holder 472 .

Further, in the ninth embodiment, a container 76 containing abrasive grains 471C (here, diamond powder) is prepared. Then, the tip portion of the holder 472 coated with the adhesive 471B (adhesive that does not contain abrasive grains) is brought into contact with the abrasive grains 471C in the container 76, and the adhesive 471B is coated with the abrasive grains. 471C is deposited. As a result, in the ninth embodiment, the adhesive 471A containing abrasive grains can be applied to the tip portion of the holder 472 .

A container containing the adhesive 471A containing abrasive grains is prepared, and the adhesive 471A containing abrasive grains is held by bringing the tip of the holder 472 into contact with the liquid surface of the adhesive 471A in the container. It is also possible to apply to the tip of body 472 . However, as in the ninth embodiment, the tip of the holder 472 coated with the adhesive 471B (adhesive that does not contain abrasive grains) is brought into contact with the abrasive grains 471C in the container 76. Then, the density of the abrasive grains 471C can be increased toward the tip side.

In the ninth embodiment, after an adhesive 471A containing abrasive grains is applied to the tip of the holding body 472, the tip of the holding body 472 is directed vertically upward and the adhesive 471A is heated to cure the adhesive 471A. Let When the adhesive 471A is heated while the tip of the holder 472 faces vertically upward, the uncured adhesive flows from the tip of the holder 472 toward the proximal end. On the other hand, since the adhesive flowing toward the base end has a low abrasive grain density (light), the side surface of the holder 472 is coated with an adhesive that contains almost no abrasive grains. Therefore, when the adhesive is cured after being heated, the adhesive flowing from the distal end side to the proximal end side forms the coated portion 471B' on the side surface of the holder 472. As shown in FIG. On the other hand, the cutting edge portion 471 is formed at the tip portion of the holder 472 by hardening the adhesive 471A containing abrasive grains at a high density.

According to the method for manufacturing the blade body 47 of the ninth embodiment, similarly to the eighth embodiment, the step of preparing the holder 472 and the adhesive 471A containing abrasive grains are applied to the tip of the holder 472. forming a cutting edge portion 471 on the portion, and forming a coating portion (coated portion) covering the base end side of the holding body 472 from the tip end portion. As a result, the abrasive grains can be arranged only at the tip portion of the blade body 47, and the area where the abrasive grains are arranged on the side surface of the blade body 47 can be narrowed. Also in the ninth embodiment, as in the eighth embodiment described above, there is no step of removing the adhesive 471A applied to the holder 472, so the manufacturing process can be simplified.

Further, according to the method for manufacturing the blade body 47 of the ninth embodiment, the coating portion 472B' is formed on the side surface of the holder 472 by the adhesive flowing from the distal end side to the proximal end side. Such a coat portion 471B' is composed of an adhesive that contains almost no abrasive grains, and has a smooth surface. Therefore, even if the cut surface of the optical fiber 1 comes into contact with the side surface of the blade body 47, damage to the cut surface of the optical fiber 1 can be suppressed.

===Others===
The above-described embodiments are intended to facilitate understanding of the present invention, and are not intended to limit and interpret the present invention. The present invention can be modified and improved without departing from its spirit, and it goes without saying that the present invention includes equivalents thereof.

1 optical fiber, 3 holder, 5 waste material case,
10 base member, 11 holder mounting portion,
13 guide part, 15 operation part,
15A rotating portion, 15B housing portion, 15C latch releasing portion,
40 moving member, 41 moving body,
41A case accommodating portion, 41B mounting surface, 41C engagement hole,
45 gripping member, 45A rotating part,
45B clamp portion, 45C locking portion,
46 wound forming part, 46A rotating part,
47 blade body, 471 cutting edge portion, 471A adhesive (containing abrasive grains),
471B adhesive (without abrasive grains), 471B' coated portion, 471C abrasive grains,
472 holding body, 472A mounting portion,
48 bending portion, 50 latch portion,
51 base side latch portion, 54 moving side latch portion,
60 tensioning spring;
71 mold, 72 coating member (fourth embodiment, grease),
73 Coat member (fifth embodiment, tape member)
74 Coat member (eighth embodiment, tape member)
75 container, 76 container,
100 fiber cutter

Claims (1)

providing a support;
Forming a cutting edge portion at the tip portion of the holding body with an adhesive containing abrasive grains, and forming a coat portion covering the base end side of the tip portion,
After applying an adhesive containing abrasive grains to the tip of the holding body, the adhesive flowing from the tip to the base end by heating with the tip facing up causes the coated portion to A method for manufacturing a blade body for an optical fiber cutter, characterized by forming

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