Abstract: An optical fiber re-coating device of the invention includes an optical fiber coater that includes: an inner glass opening-and-closing unit including: a pair of glass members having grooves formed thereon; and a pair of mounting tables which are coupled to each other via a first hinge; and an outer opening-and-closing unit including: a pair of covers which are coupled to each other via a second hinge, one of the paired covers having a magnet provided therein, the other of the paired covers having a magnet catch provided therein, the magnet and the magnet catch facing each other when the paired covers are in a closed state; and light sources that cure a resin used to coat an optical fiber provided in the inner glass opening-and-closing unit and are provided in the respective paired covers.

Abstract: An optical fiber holding device of the invention includes a holder that includes a base and a lid which are openable and closable, sandwiches an optical fiber when the base and the lid are in a closed state, and thereby holds the optical fiber. The holder includes: an elastic body; a drive unit configured to generate driving power; and a pusher. The pusher is configured to generate a pressing force based on the driving power generated by the drive unit and press the lid by the pressing force via the elastic body. The lid and the base are configured to sandwich and hold the optical fiber based on the pressing force transmitted through the elastic body when the lid is pressed by the pusher via the elastic body.

Abstract: An optical fiber re-coating device of the invention includes an optical fiber coater that includes: a pair of glass members having grooves formed thereon; and two bases on which the respective glass members are provided, wherein at least one of the paired glass members has a cross section in a direction vertical to a mounting surface of the bases, the cross section is formed in a trapezoidal shape, the groove is provided on a short side of the trapezoidal shape, and an inclined surface of the glass member including an inclined side of the trapezoidal shape is pressed, and the glass member is thereby fixed to the base.

Abstract: A device for bending an optical fiber and receiving light is provided with a recessed holding member having a recess, a projecting holding member having a projection projecting toward the recess, light receiving elements for receiving leak light from an optical fiber held between the recess and the projection, and a supplemental support mechanism that is substantially independent of the recess or the projection and supplementarily supports the optical fiber between the recess and the projection such that the leak light from the optical fiber is received by center of the light receiving elements.

Abstract: An optical-fiber-spliced portion reinforcing heating device of the invention includes: a pair of clamps that respectively grasp a coated portion of an optical fiber, the optical fiber including a fusion-spliced portion, the fusion-spliced portion being coated with a sleeve, the coated portion being exposed from the sleeve; at least two or more heaters that are arranged to face each other so as to sandwich the sleeve; a first force-applying member that presses at least one of the paired clamps so as to apply a tension to the optical fiber; and a second force-applying member that applies a pressing force to at least one or more of the heaters via the sleeve by use of one of an elastic member and a magnetic member in accordance with control of a drive source, the heaters being arranged to face each other with the sleeve interposed therebetween.

Abstract: An optical-fiber-spliced portion reinforcing heating device of the invention includes: a pair of clamps that respectively grasp a coated portion of an optical fiber, the optical fiber including a fusion-spliced portion, the fusion-spliced portion being coated with a sleeve, the coated portion being exposed from the sleeve; at least two or more heaters that are arranged to face each other so as to sandwich the sleeve; a first force-applying member that presses at least one of the paired clamps so as to apply a tension to the optical fiber; and a second force-applying member that applies a pressing force to at least one or more of the heaters via the sleeve by use of one of an elastic member and a magnetic member in accordance with control of a drive source, the heaters being arranged to face each other with the sleeve interposed therebetween.

Abstract: In an optical-fiber-spliced portion reinforcing heating device of the invention, a pressing force that is applied to a sleeve by a second force-applying member is greater than a tension that is applied to an optical fiber by a first force-applying member; in a state in which a tension is applied to the optical fiber by the first force-applying member, a backward movable range of one clamp that applies a tension is ensured in the longitudinal direction of the optical fiber and in a direction away from heater; and as a result of ensuring a forward movable range in which it can move toward the heater, one clamp moves in a direction in which a tension that is applied to the optical fiber as a result of pressing the sleeve by the heaters and by the second force-applying member is diminished.

Abstract: A fusion splicing apparatus includes discharge electrodes 13 and 15 to discharge-heat and fusion-splice end faces 5a and 7a of optical fibers 1 and 3, fiber holders 17 and 19 to hold the optical fibers 1 and 3, V-groove blocks 21 and 23 to receive, position, and fix parts of the optical fibers 1 and 3 on the end face sides of the fiber holders 17 and 19, V-groove-block moving mechanisms 33 and 35 to move the V-groove blocks 21 and 23 so as to shift an axial center of the optical fibers 1 and 3 from a straight line between the discharge electrodes 13 and 15, and holder moving mechanisms 37 and 39 to move the fiber holders 17 and 19 so as to shift the axial center of the optical fibers 1 and 3 from the straight line between the discharge electrodes 13 and 15.

Abstract: An optical fiber fusion splicer includes: a windshield cover that is formed so as to be openable and closable and that includes one or more cover members that cover a heat fusion portion in a closed state; a pair of fiber mounting portions that are provided on left and right sides of the heat fusion portion; a pair of fiber mounting detectors that are provided in the fiber mounting portions and that detect that an optical fiber has been mounted. Also, when both the fiber mounting detectors detect that the optical fibers have been mounted in a state where the cover member is open, an operation to close the cover member is performed, the fusion splice is performed, connection portion inspection is performed, and an operation to open the windshield cover is performed after the connection portion inspection is completed.

Abstract: In an optical-fiber-spliced portion reinforcing heating device of the invention, a pressing force that is applied to a sleeve by a second force-applying member is greater than a tension that is applied to an optical fiber by a first force-applying member; in a state in which a tension is applied to the optical fiber by the first force-applying member, a backward movable range of one clamp that applies a tension is ensured in the longitudinal direction of the optical fiber and in a direction away from heater; and as a result of ensuring a forward movable range in which it can move toward the heater, one clamp moves in a direction in which a tension that is applied to the optical fiber as a result of pressing the sleeve by the heaters and by the second force-applying member is diminished.

Abstract: A device for applying electric discharge on an optical fiber by electrodes is comprised of a first driving mechanism for controllably driving the electrodes in a first direction perpendicular to an axial direction of the optical fiber; and a second driving mechanism for controllably and synchronously driving the electrodes in a second direction perpendicular to the axial direction of the optical fiber but not identical to the first direction.

Abstract: An optical-fiber-spliced portion reinforcing heating device of the invention includes: clamps, a fifth force-applying member that sandwiches an optical fiber and applies a pressing force thereto; a first cam mechanism; a mechanism in which displacement of first cam mechanism controls to grasp the optical fiber by the clamps; heaters; a second force-applying member that sandwiches the sleeve and applies a pressing force thereto; a third cam mechanism; and a mechanism in which displacement of the third cam mechanism control to press the sleeve by the heaters. The same motor controls a force of each force-applying member of the clamps and the heaters by the first and third cam mechanism.

Abstract: An optical fiber fusion splicer includes: a windshield cover that is formed so as to be openable and closable and that includes one or more cover members that cover a heat fusion portion in a closed state; a pair of fiber mounting portions that are provided on left and right sides of the heat fusion portion; a pair of fiber mounting detectors that are provided in the fiber mounting portions and that detect that an optical fiber has been mounted. Also, when both the fiber mounting detectors detect that the optical fibers have been mounted in a state where the cover member is open, an operation to close the cover member is performed, the fusion splice is performed, connection portion inspection is performed, and an operation to open the windshield cover is performed after the connection portion inspection is completed.

Abstract: A fusion splicer includes an imaging unit configured to take a lateral transmission image by illuminating a target optical fiber from a lateral direction of the target optical fiber; a determination module configured to create a target luminance distribution in a direction perpendicular to an optical axis of the target optical fiber using the lateral transmission image so as to determine a type of the target optical fiber, by comparing the target luminance distribution with preliminarily registered data of a reference luminance distribution of a reference optical fiber; and a registration module configured to create a message when the target luminance distribution is determined to be outside a tolerance of the reference luminance distribution and to display the message to an operator so that the operator can decide whether or not to register the target luminance distribution of the target optical fiber as a new reference luminance distribution.

Abstract: An optical fiber fusion splice system includes a working table and a storage box which stores the working table. The working table includes a fusion splicing machine installation portion accommodating a fusion splicing machine to be stored in the storage box and a working surface on which preparation work for an optical fiber is configured to be performed. The fusion splicing machine installation portion includes a fusion splicing machine restriction portion being configured to restrict the fusion splicing machine without the fusion splicing machine moving in a horizontal direction with respect to the working table. The working surface includes a protrusion provided on an outer circumference of the working surface, the protrusion being configured to prevent a tool used in the preparation work from falling from the working surface. The storage box includes a box main body and a cover which covers an upper portion of the box main body.

Abstract: A fusion splicer includes an imaging unit configured to take a lateral transmission image by illuminating a target optical fiber from a lateral direction of the target optical fiber; a determination module configured to create a target luminance distribution in a direction perpendicular to an optical axis of the target optical fiber using the lateral transmission image so as to determine a type of the target optical fiber, by comparing the target luminance distribution with preliminarily registered data of a reference luminance distribution of a reference optical fiber; and a registration module configured to create a message when the target luminance distribution is determined to be outside a tolerance of the reference luminance distribution and to display the message to an operator so that the operator can decide whether or not to register the target luminance distribution of the target optical fiber as a new reference luminance distribution.

Abstract: A fusion splicing apparatus includes discharge electrodes 13 and 15 to discharge-heat and fusion-splice end faces 5a and 7a of optical fibers 1 and 3, fiber holders 17 and 19 to hold the optical fibers 1 and 3, V-groove blocks 21 and 23 to receive, position, and fix parts of the optical fibers 1 and 3 on the end face sides of the fiber holders 17 and 19, V-groove-block moving mechanisms 33 and 35 to move the V-groove blocks 21 and 23 so as to shift an axial center of the optical fibers 1 and 3 from a straight line between the discharge electrodes 13 and 15, and holder moving mechanisms 37 and 39 to move the fiber holders 17 and 19 so as to shift the axial center of the optical fibers 1 and 3 from the straight line between the discharge electrodes 13 and 15.

Abstract: A fusion splicing apparatus fusion-splices end faces 1a and 3a of a pair of optical fibers 1 and 3 to each other. The apparatus includes a mirror shaft 21 provided with a mirror 23 that is arranged between the end faces 1a and 3a of the pair of optical fibers 1 and 3 that are faced toward and spaced away from each other and is movable between a first position to reflect an image of the end face 1a and a second position to reflect an image of the end face 3a, a first camera 25 that takes the image of the end face 1a reflected in the first position, and a second camera 27 that takes the image of the end face 3a reflected in the second position.

Abstract: A connection method connects an optical connector and an optical transmission element. The optical connector includes a connector housing, a stop-ring structure, and an optical fiber which protrudes from an end part of the stop-ring structure. The optical transmission element includes a tensile-strength fiber body. The connection method includes fuse-connecting a first end of the optical fiber with a second end of an optical fiber protruding from a transmission element terminal part of the optical transmission element; inserting a fuse-connected optical fiber part and the tensile strength fiber body inside a reinforcing sleeve provided with a hot melt body, and covering and bridging the transmission element terminal part and at least the end part of the stop-ring structure; and integrating the fuse-connected optical fiber part, the tensile strength fiber body, the transmission element terminal part, and the stop-ring structure, by a hot melt resin melted from the hot melt body.

Abstract: A sheath removing unit according to the invention includes a sheath removing blade that includes a pair of blade bodies disposed so as to face each other, and an optical fiber guide that includes first guide body and the second guide body. The first guide body includes a first protruding portion that is disposed so as to be superimposed on a first blade body of the blade bodies and protrudes from the first blade body toward a second blade body. The second guide body includes a second protruding portion that is disposed so as to be superimposed on the second blade body and protrudes from the second blade body toward the first blade body. The first protruding portion includes a lower inclined portion, which is inclined outward toward a protruding direction of the first protruding portion, on the surface thereof facing the second guide body.