Abstract: Fiber optic equipment that supports independently translatable fiber optic modules and/or fiber optic equipment trays containing one or more fiber optic modules is disclosed. In some embodiments, one or more fiber optic modules are disposed in a plurality of independently translatable fiber optic equipment trays which are received in a tray guide system. In this manner, each fiber optic equipment tray is independently translatable within the guide system. One or more fiber optic modules may also be disposed in one or more module guides disposed in the fiber optic equipment trays to allow each fiber optic module to translate independently of other fiber optic modules in the same fiber optic equipment tray. In other embodiments, a plurality of fiber optic modules are disposed in a module guide system disposed in the fiber optic equipment that translate independently of other fiber optic modules disposed within the module guide system.

Abstract: Fiber optic equipment that supports independently translatable fiber optic modules and/or fiber optic equipment trays containing one or more fiber optic modules is disclosed. In some embodiments, one or more fiber optic modules are disposed in a plurality of independently translatable fiber optic equipment trays which are received in a tray guide system. In this manner, each fiber optic equipment tray is independently translatable within the guide system. One or more fiber optic modules may also be disposed in one or more module guides disposed in the fiber optic equipment trays to allow each fiber optic module to translate independently of other fiber optic modules in the same fiber optic equipment tray. In other embodiments, a plurality of fiber optic modules are disposed in a module guide system disposed in the fiber optic equipment that translate independently of other fiber optic modules disposed within the module guide system.

Abstract: Convertible fiber optic panel/module assemblies for optical fiber connectivity, including for wall and floor-mounted connectivity applications are disclosed. The convertible fiber optic assemblies are configured to be convertible between a fiber optic panel assembly and a fiber optic module assembly, as desired. According to an exemplary embodiment, the convertible fiber optic panel/module assembly comprises a fiber optic panel to provide a fiber optic panel assembly. One or more fiber optic adapters are disposed through the fiber optic panel to provide fiber optic connectivity. If it is desired to convert the fiber optic panel assembly to a fiber optic module assembly, the fiber optic panel assembly is additionally fitted with a module housing having at least one rear fiber optic adapter disposed therein and a fiber optic cable harness connecting the at least one rear fiber optic adapter to the fiber optic adapters disposed in the fiber optic panel.

Abstract: A fiber optic assembly for supporting optical connections in a fiber optic network employing parallel optical configurations is described. In one embodiment, the fiber optic assembly includes at least two live multi-fiber components and at least one tap multi-fiber component. Optical signals are routed from one live multi-fiber component to another in a parallel optical connection configuration, with each group of optical signals corresponding to a respective group of fiber positions on each live multi-fiber component. Each group of optical signals is also routed to one of the first and second groups of fiber positions of the at least one tap multi-fiber component in a parallel optical connection configuration. In this manner, fiber optic signals can be simultaneously provided and monitored within an active fiber optic network using a parallel optical configuration without the need for interrupting network operations.

Abstract: A port tap cable for supporting live optical connections in a fiber optic network includes one or more fiber optic splitters, which each receive an optical signal from a live input optical fiber of a live input fiber optic cable leg. Each fiber optic splitter splits each optical signal and transmits the signal to a live output optical fiber of a live output fiber optic cable leg and a tap output optical fiber of a tap output fiber optic cable leg. The one or more splitters are enclosed in a furcation, thereby forming a port tap cable that allows for monitoring of optical signals within an active fiber optic network without the need for interrupting network operations. This arrangement also allows for monitoring individual ports in an existing network installation.

Abstract: Convertible fiber optic panel/module assemblies for optical fiber connectivity, including for wall and floor-mounted connectivity applications are disclosed. The convertible fiber optic assemblies are configured to be convertible between a fiber optic panel assembly and a fiber optic module assembly, as desired. According to an exemplary embodiment, the convertible fiber optic panel/module assembly comprises a fiber optic panel to provide a fiber optic panel assembly. One or more fiber optic adapters are disposed through the fiber optic panel to provide fiber optic connectivity. If it is desired to convert the fiber optic panel assembly to a fiber optic module assembly, the fiber optic panel assembly is additionally fitted with a module housing having at least one rear fiber optic adapter disposed therein and a fiber optic cable harness connecting the at least one rear fiber optic adapter to the fiber optic adapters disposed in the fiber optic panel.

Abstract: Fiber optic modules having pigtails and related strain relief constructions for the fiber optic harness are disclosed. The fiber optic module assembly has a fiber pigtail exiting module, the assembly includes a main body of the module defining an internal chamber disposed between a first side and a second side, a plurality of fiber optic components disposed at the first side of the module, and a fiber optic harness including the fiber pigtail. The fiber optic harness includes a plurality of optical fibers within a portion of a protective tube on the pigtail portion and a strain-relief assembly for inhibiting movement between the optical fibers and protective tube. Consequently, the strain-relief assembly secures the plurality of optical fibers and the protective tube to the main body of the module.

Abstract: Fiber management structures for fan-out assemblies that are used to furcate a fiber optic cable are disclosed, as are fiber optic assemblies with fiber management structures and related methods. The fiber management structures each include channels extending between opposed first and second ends. A plurality of fan-out tubes are received in the plurality of channels such that the fiber management structure organizes the fan-out tubes, thereby allowing a compact furcation body to be formed even when furcating high fiber count cables.

Abstract: A fiber optic assembly for supporting optical connections in a fiber optic network employing parallel optical configurations is described. In one embodiment, the fiber optic assembly includes at least two live multi-fiber components and at least one tap multi-fiber component. Optical signals are routed from one live multi-fiber component to another in a parallel optical connection configuration, with each group of optical signals corresponding to a respective group of fiber positions on each live multi-fiber component. Each group of optical signals is also routed to one of the first and second groups of fiber positions of the at least one tap multi-fiber component in a parallel optical connection configuration. In this manner, fiber optic signals can be simultaneously provided and monitored within an active fiber optic network using a parallel optical configuration without the need for interrupting network operations.

Abstract: Fiber management structures for fan-out assemblies that are used to furcate a fiber optic cable are disclosed, as are fiber optic assemblies with fiber management structures and related methods. The fiber management structures each include channels extending between opposed first and second ends. A plurality of fan-out tubes are received in the plurality of channels such that the fiber management structure organizes the fan-out tubes, thereby allowing a compact furcation body to be formed even when furcating high fiber count cables.

Abstract: A port tap cable for supporting live optical connections in a fiber optic network includes one or more fiber optic splitters, which each receive an optical signal from a live input optical fiber of a live input fiber optic cable leg. Each fiber optic splitter splits each optical signal and transmits the signal to a live output optical fiber of a live output fiber optic cable leg and a tap output optical fiber of a tap output fiber optic cable leg. The one or more splitters are enclosed in a furcation, thereby forming a port tap cable that allows for monitoring of optical signals within an active fiber optic network without the need for interrupting network operations. This arrangement also allows for monitoring individual ports in an existing network installation.

Abstract: Embodiments disclosed herein include furcation plugs having segregated channels to guide epoxy into passageways for optical fiber furcation, and related assemblies and methods. The furcation plugs secure furcated fiber optic cables to fiber optic equipment to prevent the furcated fiber optic cables from being damaged. The furcation plugs, as part of fiber optic furcation assemblies, are typically installed on fiber optic equipment that provides fiber optic components to which the optical fibers are connected. The fiber optic cables may be inserted into fiber passageways of the furcation plugs and secured to the furcation plugs with epoxy. The epoxy may be guided into the fiber passageways through segregated epoxy channels of the furcation plug. In this manner, epoxy may be more uniformly distributed within the fiber passageway to improve the epoxy bonds by reducing the occurrence of air pockets known as voids, which can weaken the epoxy bonds and cause attenuation.

Abstract: Fiber optic modules having pigtails and related strain relief constructions for the fiber optic harness are disclosed. The fiber optic module assembly has a fiber pigtail exiting module, the assembly includes a main body of the module defining an internal chamber disposed between a first side and a second side, a plurality of fiber optic components disposed at the first side of the module, and a fiber optic harness including the fiber pigtail. The fiber optic harness includes a plurality of optical fibers within a portion of a protective tube on the pigtail portion and a strain-relief assembly for inhibiting movement between the optical fibers and protective tube. Consequently, the strain-relief assembly secures the plurality of optical fibers and the protective tube to the main body of the module.

Abstract: A fiber optic assembly includes first and second sets of ferrules. The first set of ferrules includes a first ferrule supporting a first plurality of optical fibers including first and second groups of optical fibers, a second ferrule supporting a second plurality of optical fibers including third and fourth groups of optical fibers, and a third ferrule supporting a third plurality of optical fibers including fifth and sixth groups of optical fibers. The second set of ferrules includes a fourth ferrule and a fifth ferrule. The fourth ferrule supports optical fibers of the first, second, third, and fourth groups of optical fibers, and the fifth ferrule supports optical fibers of the third, fourth, fifth, and sixth groups of optical fibers.

Abstract: A rotatable furcation assembly for furcating optical fibers of a multi-fiber fiber-optic cable to form multiple connecting cables is disclosed. The furcation assembly includes a furcation plug having a central, longitudinal axis and an interior sized to accommodate the furcation of the optical fibers. The furcation assembly also has a clip member with a holding feature and at least one mounting feature. The holding feature has a truncated tubular body that holds the furcation plug such that the furcation plug can axially rotate.

Abstract: Embodiments disclosed herein include furcation plugs having segregated channels to guide epoxy into passageways for optical fiber furcation, and related assemblies and methods. The furcation plugs secure furcated fiber optic cables to fiber optic equipment to prevent the furcated fiber optic cables from being damaged. The furcation plugs, as part of fiber optic furcation assemblies, are typically installed on fiber optic equipment that provides fiber optic components to which the optical fibers are connected. The fiber optic cables may be inserted into fiber passageways of the furcation plugs and secured to the furcation plugs with epoxy. The epoxy may be guided into the fiber passageways through segregated epoxy channels of the furcation plug. In this manner, epoxy may be more uniformly distributed within the fiber passageway to improve the epoxy bonds by reducing the occurrence of air pockets known as voids, which can weaken the epoxy bonds and cause attenuation.

Abstract: A ferrule assembly includes a ferrule comprising a ferrule boot insertion end and a ferrule boot defining an optical fiber channel. The optical fiber channel of the ferrule boot is shaped to receive a plurality of optical fibers therethrough. The ferrule boot includes an outer shell and a heat-activated adhesive liner is positioned within the outer shell channel and coupled to the inner surface of the outer shell. A portion of the outer shell is sized to be at least partially inserted into the ferrule boot insertion end of the ferrule. The outer shell has a thermal melting point that is greater than a thermal melting point of the heat-activated adhesive liner such that the heat-activated adhesive liner melts for adhering the plurality of optical fibers to the outer shell upon receipt of thermal energy.

Abstract: Port tap fiber optic modules and related systems and methods for monitoring optical networks are disclosed. In certain embodiments, the port tap fiber optic modules disclosed herein include connections that employ a universal wiring scheme. The universal writing scheme ensure compatibility of attached monitor devices to permit a high density of both live and tap fiber optic connections, and to maintain proper polarity of optical fibers among monitor devices and other devices. In other embodiments, the port tap fiber optic modules are provided as high-density port tap fiber optic modules. The high-density port tap fiber optic modules are configured to support a specified density of live and passive tap fiber optic connections. Providing high-density port tap fiber optic modules can support greater connection bandwidth capacity to provide a migration path for higher data rates while minimizing the space needed for such fiber optic equipment.

Abstract: Port tap fiber optic modules and related systems and methods for monitoring optical networks are disclosed. In certain embodiments, the port tap fiber optic modules disclosed herein include connections that employ a universal wiring scheme. The universal writing scheme ensure compatibility of attached monitor devices to permit a high density of both live and tap fiber optic connections, and to maintain proper polarity of optical fibers among monitor devices and other devices. In other embodiments, the port tap fiber optic modules are provided as high-density port tap fiber optic modules. The high-density port tap fiber optic modules are configured to support a specified density of live and passive tap fiber optic connections. Providing high-density port tap fiber optic modules can support greater connection bandwidth capacity to provide a migration path for higher data rates while minimizing the space needed for such fiber optic equipment.

Abstract: Fiber optic equipment that supports independently translatable fiber optic modules and/or fiber optic equipment trays containing one or more fiber optic modules is disclosed. In some embodiments, one or more fiber optic modules are disposed in a plurality of independently translatable fiber optic equipment trays which are received in a tray guide system. In this manner, each fiber optic equipment tray is independently translatable within the guide system. One or more fiber optic modules may also be disposed in one or more module guides disposed in the fiber optic equipment trays to allow each fiber optic module to translate independently of other fiber optic modules in the same fiber optic equipment tray. In other embodiments, a plurality of fiber optic modules are disposed in a module guide system disposed in the fiber optic equipment that translate independently of other fiber optic modules disposed within the module guide system.