Abstract: A fixture for retaining an optical connector holder and optical fibers for splicing in an optical fiber stripping machine is disclosed. The fixture enables for two optical fibers of the connector to be appropriately aligned such that they can be simultaneously stripped in a standard optical fiber stripping machine. In one example, the fixture includes a main body extending between a first end and a second, a cavity defined within the main body the cavity, the cavity being for receiving an optical cable holder of an optical fiber connector, a first fiber retention structure for holding the optical fibers extending from the connector holder, and a second fiber retention structure for holding the optical fibers.

Abstract: Certain splice arrangements include first and second laminate structures bonded around a splice location at which two or more optical fibers are spliced (e.g., fusion spliced) together. The first and second laminate structures each include a flexible polymeric sheet and a heat activated adhesive layer carried by the flexible polymeric sheet. Other splice arrangements include a protective barrier disposed about an optical splice. The protective barrier includes first and second protective layers bonded around the optical splice. Each protective layer include a film carrying an adhesive. The protective barrier may be sufficiently flexible to not restrict flexing the optical fibers at the splice location. Example splice arrangements have thicknesses of less than or equal to 1000 microns, or 900 microns, or 800 microns, or 700 microns, or 600 microns or 500 microns.

Abstract: The present disclosure relates to a ferrule boot that provides a pitch conversion from fiber ribbon having a first pitch (e.g., about 200 microns) to a multi-fiber ferrule having fiber openings arranged at a second pitch larger than the first pitch (e.g., about 250 microns). The ferrule boot may also function as a tool for inserting pitch converted optical fibers into the multi-fiber ferrule.

Abstract: The present disclosure relates to a fiber optic cable breakout assembly that includes a transition body made from a moldable material having an inlet end and an opposite outlet end. The moldable transition body includes a centering element positioned therein and an internal splice positioned within the centering element to splice a plurality of breakout fibers to at least one cable. The centering element is configured to center the splice, the at least one cable and the plurality of breakout fibers prior to molding the transition body. The transition body is adapted to protect the splice and fibers such that no other external protection is needed.

Abstract: Certain splice arrangements include first and second laminate structures bonded around a splice location at which two or more optical fibers are spliced (e.g., fusion spliced) together. The first and second laminate structures each include a flexible polymeric sheet and a heat activated adhesive layer carried by the flexible polymeric sheet. Other splice arrangements include a protective barrier disposed about an optical splice. The protective barrier includes first and second protective layers bonded around the optical splice. Each protective layer include a film carrying an adhesive. The protective barrier may be sufficiently flexible to not restrict flexing the optical fibers at the splice location. Example splice arrangements have thicknesses of less than or equal to 1000 microns, or 900 microns, or 800 microns, or 700 microns, or 600 microns or 500 microns.

Abstract: Methods and devices for assembling a fiber optic connector are provided. A device supports at least one fiber optic connector. The connector has an optical fiber inserted through the ferrule so that an exposed portion is disposed outside of the ferrule. Residual epoxy on the exposed portion is cured prior to physically manipulating the optical fiber within the ferrule. The device includes at least one heating chamber and a heat shield for curing of the residual epoxy.

Abstract: Certain splice arrangements include first and second laminate structures bonded around a splice location at which two or more optical fibers are spliced (e.g., fusion spliced) together. The first and second laminate structures each include a flexible polymeric sheet and a heat activated adhesive layer carried by the flexible polymeric sheet. Other splice arrangements include a protective barrier disposed about an optical splice. The protective barrier includes first and second protective layers bonded around the optical splice. Each protective layer include a film carrying an adhesive. The protective barrier may be sufficiently flexible to not restrict flexing the optical fibers at the splice location. Example splice arrangements have thicknesses of less than or equal to 1000 microns, or 900 microns, or 800 microns, or 700 microns, or 600 microns or 500 microns.

Abstract: Aspects and techniques of the present disclosure relate to an apparatus for providing 200 micron, or smaller, coated optical fibers with a 250 micrometer pitch diameter in preparation for insertion into a Multi-fiber Push On connector (MPO) and/or splicing apparatus. The apparatus can sort, arrange, and clamp optical fibers into a proper sequence to allow the coated optical fibers to be aligned for processing, for example, connectorization and/or splicing. The apparatus includes a separator element that defines grooves for receiving and sequencing coated optical fibers with respect to each other to set a uniform pitch diameter.

Abstract: The present disclosure relates to a ferrule boot for mounting in a multi-fiber ferrule. The ferrule boot may include a body member that has a distal end and a proximal end. The body member may define a plurality of openings that extend lengthwise therethrough with each opening being configured for receiving a respective one of a plurality of optical fibers.

Abstract: The present disclosure incudes a fiber optic cable having a conduit including a conduit wall defining a conduit passage that extends longitudinally through the conduit. The conduit also includes an adhesive injection port defined through the conduit wall and at least one optical fiber within the conduit passage. The cable further includes a fiber lock including an adhesive volume in communication with the adhesive injection port. The adhesive volume includes a main adhesive volume positioned within the conduit passage and bonded to the optical fiber. The main adhesive volume is fixed to prevent longitudinal movement relative to the conduit.

Abstract: Processing operations allow optical fibers to be efficiently installed in ferrules. An optical fiber holding device includes a clip having a length that extends between a first end and a second end. The clip includes a base and a cover that each extend between the first end and second ends. The clip includes a fiber passage that located between the cover and the base that extends between the first and second ends. The clip defines a ferrule boot receptacle at the first end.

Abstract: The present disclosure relates generally to a method for processing an optical fiber. The coating is stripped from the cladding of the optical fiber using a stripping process. Direct heat is applied to the first side of the optical fiber and is not applied to the second side of the optical fiber. Then, the optical fiber is inserted into a fiber alignment structure with the second side of the optical fiber engaging a fiber alignment feature of the alignment structure. The first side of the optical fiber does not engage the fiber alignment feature.

Abstract: A fiber cleaving tool includes a cleaving component, a first mounting nest at a first end of the cleaving component, and a second mounting nest at an opposite second end of the cleaving component. Each mounting nest is configured to hold and orient a mounting clip to direct one or more optical fibers towards the cleaving component. The orientation of the mounting nests of the cleaving tool may correspond to the orientation of the mounting nests of a splice tool.

Abstract: The present disclosure relates to a splice arrangement. The splice arrangement may include an elongate splice protection housing that defines a channel that extends lengthwise through the elongate splice protection housing from a first end of the splice protection housing to an opposite second end of the splice protection housing. The splice arrangement may also include a first fiber optic cable and a second fiber optic cable. First optical fibers of the first fiber optic cable and second optical fibers of the second fiber optic cable may be coupled together at a splice location positioned within the channel of the elongate splice protection housing.

Abstract: The present disclosure relates to a fan-out arrangement. The fan-out arrangement may include a main cable that includes a jacket containing a plurality of optical fibers and a plurality of breakout cables that receive the optical fibers of the main cable. The fan-out arrangement may include a fan-out device for transitioning the optical fibers from the main cable to the breakout cable. The fan-out device may include a fan-out housing that includes oppositely positioned first and second housing ends. The fan-out device may also include a fiber transition insert that mounts within the fan-out housing.

Abstract: Certain splice arrangements include first and second laminate structures bonded around a splice location at which two or more optical fibers are spliced (e.g., fusion spliced) together. The first and second laminate structures each include a flexible polymeric sheet and a heat activated adhesive layer carried by the flexible polymeric sheet. Other splice arrangements include a protective barrier disposed about an optical splice. The protective barrier includes first and second protective layers bonded around the optical splice. Each protective layer include a film carrying an adhesive. The protective barrier may be sufficiently flexible to not restrict flexing the optical fibers at the splice location. Example splice arrangements have thicknesses of less than or equal to 1000 microns, or 900 microns, or 800 microns, or 700 microns, or 600 microns or 500 microns.

Abstract: The present disclosure incudes a fiber optic cable having a conduit including a conduit wall defining a conduit passage that extends longitudinally through the conduit. The conduit also includes an adhesive injection port defined through the conduit wall and at least one optical fiber within the conduit passage. The cable further includes a fiber lock including an adhesive volume in communication with the adhesive injection port. The adhesive volume includes a main adhesive volume positioned within the conduit passage and bonded to the optical fiber. The main adhesive volume is fixed to prevent longitudinal movement relative to the conduit.

Abstract: The present disclosure relates to an improved stripping process that allows for double stripping in a fiber optic cable processing apparatus. The fiber optic cable processing apparatus has a double stripping fixture that includes a first set of blades configured for stripping a buffer layer off a fiber optic cable and a second set of blades for simultaneously stripping a buffer layer and a coating layer off the fiber optic cable. The double stripping fixture can also include spacers that are configured to set a gap between the first and second sets of blades.

Abstract: Aspects and techniques of the present disclosure relate to an apparatus for providing 200 micron, or smaller, coated optical fibers with a 250 micrometer pitch diameter in preparation for insertion into a Multi-fiber Push On connector (MPO) and/or splicing apparatus. The apparatus can sort, arrange, and clamp optical fibers into a proper sequence to allow the coated optical fibers to be aligned for processing, for example, connectorization and/or splicing. The apparatus includes a separator element that defines grooves for receiving and sequencing coated optical fibers with respect to each other to set a uniform pitch diameter.

Abstract: The present disclosure relates to a ferrule boot for mounting in a multi-fiber ferrule. The ferrule boot may include a body member that has a distal end and a proximal end. The body member may define a plurality of openings that extend lengthwise therethrough with each opening being configured for receiving a respective one of a plurality of optical fibers.