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: 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: 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 relates to a handheld tool for scoring a jacket of a fiber optic cable. The handheld tool includes a U-shaped channel seat for supporting the fiber optic cable and a scoring head configured to support a cutting blade. The cutting blade can be fixed to the scoring head by a fastener and can be adjusted by utilizing a set screw. A blade setting block can be used to calibrate or adjust the cutting blade position prior to the operation of scoring the jacket of the fiber optic cable.

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: A tool for removing a ferrule alignment sleeve from a sleeve mount of a fiber optic adapter, wherein the sleeve mount defines an axial bore and radially inwardly extending fingers for retaining the ferrule alignment sleeve therewithin, includes a handle and a pin extending from the handle. The pin is configured to slidably receive the ferrule alignment sleeve, the pin defining longitudinal keys for mating with gaps defined between the radially inwardly extending fingers of the sleeve mount, wherein the tool can also be used as a ferrule alignment sleeve insertion tool if the pin is inserted into the axial bore in a different orientation and from an opposite end of the axial bore as compared to the removal function.

Abstract: A tool is disclosed. The tool is for inserting a ferrule alignment sleeve within a sleeve mount of a fiber optic adapter, wherein the sleeve mount defines an axial bore and radially inwardly extending fingers for retaining the ferrule alignment sleeve therewithin. The tool includes a handle and a pin extending from the handle, the pin configured to slidably receive the ferrule alignment sleeve, the pin defining longitudinal keys for mating with gaps defined between the radially inwardly extending fingers of the sleeve mount, wherein the tool can be used as a ferrule alignment sleeve insertion tool if the pin is inserted into the axial bore in a first orientation and is configured to be used as a ferrule alignment sleeve removal tool if the pin is inserted into the axial bore in a second orientation from an opposite end of the axial bore.

Abstract: A tool is disclosed. The tool is for inserting a ferrule alignment sleeve within a sleeve mount of a fiber optic adapter, wherein the sleeve mount defines an axial bore and radially inwardly extending fingers for retaining the ferrule alignment sleeve therewithin. The tool includes a handle and a pin extending from the handle, the pin configured to slidably receive the ferrule alignment sleeve, the pin defining longitudinal keys for mating with gaps defined between the radially inwardly extending fingers of the sleeve mount, wherein the tool can be used as a ferrule alignment sleeve insertion tool if the pin is inserted into the axial bore in a first orientation and is configured to be used as a ferrule alignment sleeve removal tool if the pin is inserted into the axial bore in a second orientation from an opposite end of the axial bore.

Abstract: A tool is disclosed. The tool is for inserting a ferrule alignment sleeve within a sleeve mount of a fiber optic adapter, wherein the sleeve mount defines an axial bore and radially inwardly extending fingers for retaining the ferrule alignment sleeve therewithin. The tool includes a handle and a pin extending from the handle, the pin configured to slidably receive the ferrule alignment sleeve, the pin defining longitudinal keys for mating with gaps defined between the radially inwardly extending fingers of the sleeve mount, wherein the tool can be used as a ferrule alignment sleeve insertion tool if the pin is inserted into the axial bore in a first orientation and is configured to be used as a ferrule alignment sleeve removal tool if the pin is inserted into the axial bore in a second orientation from an opposite end of the axial bore.