Abstract: Fiber optic connectors and connectorized fiber optic cables include connector housings having locking portions defined on the connector housing that allow the connector housing to be selectively coupled to a corresponding push-button securing member of a multiport assembly. Methods for selectively connecting a fiber optic connector to and disconnecting the fiber optic connector from the multiport assemblies allow for connector housings to be forcibly and nondestructively removed from the multiport assembly.

Abstract: A cable fixation structure for fixing at least a portion of a fiber optic cable to a telecommunications fixture against strain relief includes a cable bracket portion and a base portion, wherein the cable bracket portion is configured for fixing the at least a portion of the fiber optic cable and the base is configured for routing fibers extending from the fiber optic cable, wherein the cable bracket portion is provided at an acute angle with respect to a vertical plane passing through a longitudinal axis defined by the base portion.

Abstract: A fiber management system for managing and distributing optical fibers comprises at least one supporting element, at least one splice tray pivotally mounted on the supporting element around a pivot axis (X), distributing elements for routing incoming fiber modules toward the splice tray and for routing outgoing fiber modules away from the splice tray, the distributing elements being oriented along respective routing directions transverse to the pivot axis. At least one guiding channel is provided on the supporting element for guiding at least the incoming fiber modules toward the splice tray along a direction substantially parallel to the pivot axis (X), and a retention block acts into the guiding channel between a plurality of retention positions wherein each retention position of the retention block defines a respective passageway for the incoming fiber modules.

Abstract: A housing including a plurality of openings for receiving fiber optic connectors and protecting the polished end face of the connectors from damage while the connectors are stored within a telecommunications connection cabinet. A module with a plurality of optical fiber cables connected to a first optical fiber cable and terminated by a fiber optic connector. Each of the connectors are inserted within openings in a connector holder for storage and protection until the cables need to be connected to a customer equipment cable.

Abstract: Pairs of windows are cut into a distribution cable at various points along the length to couple some of the optical fibers of the distribution cable to drop cables. A wrap-type sealing arrangement can seal a first window of each pair. An enclosure-type sealing arrangement can seal a second window of each pair. The enclosure includes a splice tray and cable storage. Optical adapters and/or a passive splitter also may be disposed within the enclosure.

Abstract: An optical fiber routing assembly for interfacing with co-package optical (CPO) modules is disclosed. The optical fiber routing assembly includes a housing, a plurality of terminated optical fibers routed within the housing, a first set of adapters, and a second set of adapters. The first set of adapters is arranged vertically on an upper panel of the housing and facilitates connecting the plurality of terminated optical fibers to the CPO modules via terminated jumper optical fibers. The second set of adapters is arranged horizontally and configured to facilitate connecting the plurality of terminated optical fibers to one or more electronic systems. A combination of the first set of adapters and the second set of adapters facilitates communication between the CPO modules and the electronic systems. The optical fiber routing assembly provides fiber management to alleviate maintenance or heat issues associated with dense fiber routing around electronic components.

Abstract: High density optical fiber distribution sub-rack comprising: a chassis for housing a plurality of shelves, the chassis comprising at least two shelf storage areas placed side by side with each other, at least one shelf housed in one of the at least two storage areas of the chassis, the at least one shelf having an internal hollow seat for connection modules, the at least one shelf comprising one or more connection modules having a plurality of adapters for interconnection optical fibers, the connection modules being arranged in the internal hollow seat of the at least one shelf at the frontal face of the at least one shelf, wherein the at least one shelf is guided so as to be movable towards the external of the chassis by the succession of a translation movement and a rotation movement of the at least one shelf.

Abstract: A terminal system assembly includes a base plate, a spool, an adapter module for securing a connection between a fiber of an input fiber cable and a fiber of an output fiber cable, and a cable management plate coupled with the spool. The spool is rotatably mounted to the base plate and is configured to receive the input fiber cable. The adapter module is configured to be coupled with the cable management plate. The spool containing the fiber input cable is allowed to freely rotate until the adapter module is coupled with the cable management plate. The adapter module includes an anti-rotation portion that is configured to cooperate with a portion of the base plate to prevent rotation of the spool and the adapter module when the adapter module is coupled with the spool.

Abstract: A telecommunications assembly includes a chassis defining an interior region and a tray assembly disposed in the interior region. The tray assembly includes a tray and a cable spool assembly. The cable spool assembly is engaged to a base panel of the tray. The cable spool assembly is adapted to rotate relative to the tray. The cable spool assembly includes a hub, a flange engaged to the hub and an adapter module. The flange defines a termination area. The adapter module is engaged to the termination module of the flange. The adapter module is adapted to slide relative to the flange in a direction that is generally parallel to the flange between an extended position and a retracted position.

Abstract: A fiber optic distribution terminal includes a cable spool rotatably disposed within an enclosure; an optical power splitter and a termination region carried by the cable spool; an optical cable deployable from the enclosure by rotating the cable spool by pulling on a connectorized end of the optical cable; and splitter pigtails extending between the optical power splitter and the termination region. One fiber of the optical cable extending between the connectorized end and the splitter input. The other fibers of the optical cable extend to a multi-fiber adapter.

Abstract: The present description relates to a modular, reconfigurable splice tray system that comprises a splice tray having a base extending longitudinally from a first end to a second end, a pair of side walls extending longitudinally between the first and second ends of the base, a plurality of cable entrances formed at the first and second end of the base and a receiving portion configured to receive a modular component disposed between the cable entrances at the first end and at the second end.

Abstract: A modular networking hardware platform utilizes a combination of different types of units that are pluggable into cassette endpoints. The present disclosure enables the construction of an extremely large system, e.g., 500 Tb/s+, as well as small, standalone systems using the same hardware units. This provides flexibility to build different systems with different slot pitches. The hardware platform includes various numbers of stackable units that mate with a cost-effective, hybrid Printed Circuit Board (PCB)/Twinax backplane, that is orthogonally oriented relative to the stackable units. In an embodiment, the hardware platform supports a range of 14.4 Tb/s-800 Tb/s+ in one or more 19? racks, providing full features Layer 3 to Layer 0 support, i.e., protocol support for both a transit core router and full feature edge router including Layer 2/Layer 3 Virtual Private Networks (VPNs), Dense Wave Division Multiplexed (DWDM) optics, and the like.

Abstract: The present invention provides modular trays having cutout features that are configured to engage with a mounting feature of one or more removable rails. The removable rails may be removably secured to a tray body in a plurality of positions to allow a user to install or uninstall rails to support different sized fiber optic modules. For example, a tray may support a twenty-four optical fiber module, two twelve optical fiber modules, or three eight optical fiber modules. Fiber optic enclosures housing the trays can be affixed to the outside of a fiber optic enclosure and allow for easy stacking and unstacking.

Abstract: An optical module includes a housing; an optical adapter arrangement disposed at the housing; a cable inlet leading from an exterior of the housing to the interior of the housing; and a splice location disposed within the interior of the housing. Optical pigtails extend from the optical adapter arrangement to the splice location. Certain types of modules have a removable splice tray having a bend radius limiting arrangement surrounding multiple splice channels. Certain types of modules have first and second chambers separated by a wall defining a pass-through aperture.

Abstract: A photonic integrated circuit may be coupled to an optical fiber and packaged. The optical fiber may be supported by a fiber holder during a solder reflow process performed to mount the packaged photonic integrated circuit to a circuit board or other substrate. The optical fiber may be decoupled from the fiber holder, and the fiber holder removed, after completion of the solder reflow process.

Abstract: An optical fiber splice enclosure includes a cap enclosing an inner volume, the cap having an access opening for accessing the inner volume. The enclosure includes a base removably attached to the access opening of the cap, the base having one or more ports for access of optical cables into the inner volume, and a fiber routing frame mounted on the base and arranged into the inner volume. The enclosure includes a tubular element arranged in the inner volume and surrounding the fiber routing frame. The tubular element has a first edge portion and a second edge portion, the tubular element including first retaining elements arranged at the first edge portion, and second retaining elements arranged at the second edge portion. The tubular element includes a bottom tubular portion proximate to the base, a top tubular portion distal to the base, and one or more frangible lines.

Abstract: An interconnect system for a building includes a pre-terminated trunk cable assembly that has different groups of optical fibers carried by subunits and terminated by ferrules. The interconnect system also includes trays for managing interconnections with the ferrules. A plurality of adapters are disposed on each tray and arranged in a direction along a longitudinal axis of the tray. The adapters may be oriented at an angle relative to the longitudinal axis to facilitate routing of the optical fibers. At least one tray mount receiver may also be provided on each tray to cooperate with a tray mount that can secure a select subunit to the tray.

Abstract: A telecommunications panel assembly (10) includes a chassis (14) defining a front (16), a top (20), a bottom (22), and two sides (24) and a plurality of adapter mounting modules (26) mounted to the chassis (14) at the front (16), each adapter mounting module (26) including a plurality of fiber optic adapters (36) mounted in a line. At least one of the adapter mounting modules (26) is mounted to the chassis (14) with a pair of supports (50) that are pivotable with respect to the at least one adapter module (26) such that the at least one adapter module (26) is removable from the chassis (14) and remountable at a position spaced linearly apart from another of the adapter mounting modules (26), wherein all of the adapter mounting modules (26) are also pivotally mounted about horizontal rotation axes (42) extending parallel to the top (20) and bottom (22) and transversely to the sides (24).

Abstract: In one form, an organizing member for optical components includes an elongate body extending about a hollow interior portion and including a peripheral sidewall. The organizing member also includes an optical fiber routing surface extending from the peripheral sidewall toward the hollow interior portion, and a recessed portion is positioned between the peripheral sidewall and the hollow interior portion. The recessed portion includes a number of receptacles offset from the optical fiber routing surface and corresponding in configuration to a respective optical component positionable therein.

Abstract: A modular high density communications chassis including a chassis, pull-out cable management system (POCMS), and at least two or more slidable carrier modules (carrier module(s)) is provided. The carrier modules are slidably mounted to the chassis and POCMS vertically, respectively. The POCMS is assembled to the chassis. In an operational position, ends of the carrier modules of the chassis extend outward from an access mounting opening of the chassis and ends of the carrier modules of the POCMS, alternately neighboring, lie flush with a plane of the access mounting opening. A handle of the POCMS is configured to move the POCMS from the operational position to a cable management position, whereby, the ends of the carrier modules of the POCMS extend past the ends of the carrier modules of the chassis, providing staged access to the carrier modules and staged management of connector cables extending to and therefrom.

Abstract: A high-density optical module system of the present invention comprises: a multi-tier housing assembly, multiple sliding tray assemblies engaged inside each of the multi-tier housing assembly and is moveable inwardly and outwardly within the multi-tier housing assembly with the handle bar; and a multiple rows of the multi-port modules arranged in horizontal arrays containing plural ports connected to the cable adaptors, wherein the multi-port modules are fastened into the sliding tray assembly. The height of the high-density optical module system is approximately 1RU (19 inches) containing at least 216 LC or 108 SC multiple connector ports.

Abstract: A fiber optic tray system includes a tray. The tray includes a tray body, the tray body extending along a longitudinal axis between a front and a rear and extending along a lateral axis between a first side and a second side. The tray further includes a plurality of alignment rails, each of the plurality of alignment rails protruding from the tray body along a transverse axis. The tray further includes a plurality of retainer features disposed at the rear of the tray body. The fiber optic tray system further includes a fiber optic module, the fiber optic module including an outer housing and at least one retainment feature. The at least one retainment feature is interfaced with at least one of the plurality of retainer features to retain the fiber optic module on the tray.

Abstract: A cable management arrangement (1000) is disclosed. In one aspect, a plurality of cables (1002) extending between first and second ends is provided. The arrangement (1000) can also include a supporting sheet (1004) having a first side and a second side, wherein the plurality of cables (1002) is removably adhered to the supporting sheet first side by a first adhesive (1010). A second adhesive (1012) can be provided on at least a portion of the supporting sheet second side and a protection sheet (1014) can be provided to cover the second adhesive (1012). A protection sheet (1014) can be provided that is removable from the supporting sheet (1004) to allow the supporting sheet (1004) to be adhered to a surface. A telecommunications arrangement is also disclosed in which the aforementioned cable management arrangement (1000) is mounted to a telecommunications tray (112) via the second adhesive (1012).

Abstract: It is disclosed a connection box for housing a connection between a distribution cable and a drop cable of an optical access network. The connection box comprises an outer casing and a detachable connection plate, which may be completely housed therein. The outer casing comprises a fixing member for fixing the distribution cable. The connection plate comprises a first surface with a fixing member for fixing an end of the drop cable and a second, opposite surface with a connector holder for holding the optical connector between a distribution fiber extracted from the distribution cable and a drop fiber extracted from the drop cable. The perimeter edge of the connection plate exhibits an indentation forming a fiber passage allowing the drop fiber passing from the first surface to the second surface of the connection plate. It is also disclosed a method for connecting two optical cables using such connection box.

Abstract: An optical fiber distribution system including a rack and elements which populate the rack including fiber terminations. Each element includes a chassis and a movable tray. The movable tray includes a synchronized movement device for moving a cable radius limiter. The tray includes cable terminations which extend in a line generally parallel to a direction of movement of the movable tray. Each of the cable terminations are mounted on hinged frame members positioned on each tray. The cables entering and exiting the movable tray follow a generally S-shaped pathway.

Abstract: An optical fiber cable management panel includes drawer assemblies, each including a drawer slidable within a chassis. The drawer assemblies are secured together by a bracket that includes an interlock arrangement with the chassis. Such an interlock arrangement includes a non-threaded stud engaging a hole. Radius limiters may be part of the drawer assembly and include a cable entry aperture have a closed perimeter and a flared cable guide surface around most of, and preferably all of, the closed perimeter to allow for the entry of cables from all directions. A control mechanism controls movement of the radius limiter relative to the drawer assembly. The control mechanism includes a rotating member that has an axis of rotation transverse to the slidable motion of the radius limiter and normal to the radius limiter.

Abstract: The present invention relates to an optical fibers management system comprising: a supporting frame; a plurality of splice trays pivotably mounted on the supporting frame and rotatable around respective parallel pivot axes between a closed position and an open position; a locking device pivotably mounted on the supporting frame and rotatable around a locking device rotation axis parallel to the pivot axes of the plurality of splice trays between a locking position and a support position, wherein in the locking position the locking device keeps the plurality of trays in the closed position, and in the support position the locking device supports the plurality of splice trays in the open position.

Abstract: An adapter panel arrangement including a chassis and a panel of adapters. The adapters defining open rearward cable connections and open forward cable connections of the panel arrangement. The adapters being arranged in arrays that slide independently of other adapter arrays to provide access to the open rearward and open forward cable connections.

Abstract: A connector assembly includes a connector and a fixing device. The connector has a housing, a ferrule mounted in the housing, and a rear body inserted into a rear end of the housing. The fixing device is connected to the rear body of the connector. The fixing device has a fixture formed in a single integrated piece. The fixture includes a connection part located at a front end of the fixture and configured to be connected to the rear body of the connector and a flexible protection part disposed adjacent to the connection part and configured to protect a cable passing therethrough.

Abstract: High-connection density and bandwidth fiber optic apparatuses and related equipment and methods are disclosed. In certain embodiments, fiber optic apparatuses are provided and comprise a chassis defining one or more U space fiber optic equipment units. At least one of the one or more U space fiber optic equipment units may be configured to support particular fiber optic connection densities and bandwidths in a given 1-U space. The fiber optic connection densities and bandwidths may be supported by one or more fiber optic components, including but not limited to fiber optic adapters and fiber optic connectors, including but not limited to simplex, duplex, and other multi-fiber fiber optic components. The fiber optic components may also be disposed in fiber optic modules, fiber optic patch panels, or other types of fiber optic equipment.

Abstract: High-connection density and bandwidth fiber optic apparatuses and related equipment and methods are disclosed. In certain embodiments, fiber optic apparatuses are provided and comprise a chassis defining one or more U space fiber optic equipment units. At least one of the one or more U space fiber optic equipment units may be configured to support particular fiber optic connection densities and bandwidths in a given 1-U space. The fiber optic connection densities and bandwidths may be supported by one or more fiber optic components, including but not limited to fiber optic adapters and fiber optic connectors, including but not limited to simplex, duplex, and other multi-fiber fiber optic components. The fiber optic components may also be disposed in fiber optic modules, fiber optic patch panels, or other types of fiber optic equipment.

Abstract: A splice distributor includes: a housing with at least one input opening for receiving an input cable, which includes at least one input optical waveguide and at least one connection opening for receiving at least one connecting optical waveguide, which is connected to the input optical waveguide in the housing in a light-conducting manner; and a splice tray arranged in the housing, which is provided on an upper side of the splice tray for receiving a connecting region of the input optical waveguide and of the connecting optical waveguide. The input opening is arranged at least partially above an upper lateral plane of the splice tray and at least one connection opening is arranged below the upper lateral plane of the splice tray.

Abstract: A shuffle assembly for a computing device comprises at least one chassis waveguide shuffle block having a plurality of chassis inputs and a plurality of chassis outputs, and having a plurality of optical waveguides formed therein connecting the chassis inputs to the chassis outputs in a desired chassis shuffle arrangement. The shuffle assembly may further comprise at least one line card waveguide shuffle block having a plurality of line card inputs, at least one of the plurality of line card inputs, a plurality of line card outputs, and a plurality of waveguides formed therein connecting the plurality of line card inputs to the plurality of line card outputs in a line card shuffle arrangement. At least one optical ribbon cable may couple the at least one chassis waveguide shuffle block to the at least one waveguide shuffle block.

Abstract: Disclosed herein is a method including wrapping a self-amalgamating tape around a portion of a cable jacket of the fiber optic cable to provide a wrapped portion; and clamping the fiber optic cable at the wrapped portion with a clamp. Upon clamping, the self-amalgamating tape is between the clamp and the cable jacket and the clamp compresses the self-amalgamating tape.

Abstract: A connector extracting jig according to an embodiment is a connector extracting jig for extracting an optical connector connected to a component to be connected along a connection direction from the component to be connected, the optical connector including a latch engaged with the component to be connected, the latch having a protrusion which is can be pushed down, and the protrusion releasing the engagement of the latch with the component to be connected when being pushed down, the connector extracting jig including: a butting part configured to butt on the optical connector in the connection direction; and a pushing-down part configured to be positioned closer to the component to be connected than the butting part and face the protrusion along a first direction intersecting the connection direction when the butting part butts on the optical connector.

Abstract: A cable enclosure assembly includes an enclosure, a cable spool and a length of fiber optic cable. The enclosure defines an interior region, a first opening and a second opening aligned with the first opening. The first and second openings provide access to the interior region. The cable spool is disposed in the interior region of the enclosure and is rotatably engaged with the enclosure. The cable spool includes a drum and a flange engaged to the drum. The flange has an outer peripheral side, a cable management portion and an adapter bulkhead portion. The adapter bulkhead portion extends outwardly from the cable management portion and forms a portion of the outer peripheral side. The length of the fiber optic cable is dispose about the drum of the cable spool.

Abstract: A drawer slide having first and second rails interconnected by a center rail. The center rail includes a spool configured to provide half-speed travel of the center rail relative to the travel of the first rail. The drawer slide is configured for use with a drawer assembly having a drawer and a chassis. The drawer assembly further includes a radius limiter secured to the center rail. The radius limiter travels at half-speed relative to the drawer. The radius limiter also automatically rotates relative to the travel of the drawer. The chassis includes sides including threaded backing plates, and mounting brackets. The mounting brackets include tri-lobed holes for receipt of a reciprocally shaped washer and a fastener for mounting the brackets to the chassis sides.

Abstract: A mounting system (700/900) for locking two pieces of telecommunications equipment (610/810) to prevent relative sliding therebetween and relative separation therebetween in a direction generally perpendicular to the direction of the relative sliding includes a first locking feature (701/901) defined by a stud (702/902) with a stem portion (708/908) and a flange portion (710/910) having a larger profile than the stem portion (708/908) and a second locking feature (703/903) defined by a slot (704/904) with a receiver portion (712/912) and a retention portion (714/914). The receiver portion (712/912) is sized to accommodate the flange portion (710/910) of the stud (702/902) and the retention portion (714/914) is sized to accommodate the stem portion (708/908) but not the flange portion (710/910) of the stud (702/902).

Abstract: A pivot interlock for a fiber management tray is disclosed. The pivot interlock is configured for pivotally coupling the fiber management tray to a tray mount. The pivot interlock includes a pivot guide portion and a pivot detent portion.

Abstract: A cable manager includes a backbone assembly and at least one side wall extending from the backbone assembly. The at least one side wall optionally includes one or more cable finger units. The backbone assembly includes a spine member having an extruded construction. The spine member includes one or more channels extending substantially an entire length thereof to facilitate easy attachment, removal and/or repositioning of a structure relative to the spine member. The cable manager optionally includes an accessory rod, a half-spool assembly, a cable finger accessory, a strap/buckle accessory, and/or a door assembly having an interference-free hinge set.

Abstract: An adapter panel arrangement including a chassis and a panel of adapters. The adapters defining open rearward cable connections and open forward cable connections of the panel arrangement. The adapters being arranged in arrays that slide independently of other adapter arrays to provide access to the open rearward and open forward cable connections.

Abstract: A fiber optic adapter block is disclosed. The fiber optic adapter block includes at least three fiber optic adapters provided in a stacked arrangement extending widthwise in a longitudinal direction, wherein every other adapter of the at least three fiber optic adapters is staggered in a front to back direction with respect to an adjacent adapter such that front ends of the every other adapter of the at least three fiber optic adapters are aligned at a first depth and a front end of the adjacent adapter is at a second depth that is different than the first depth.

Abstract: Aspects and techniques of the present disclosure relate to an enclosure (10) including a housing, a volume of sealant (66) that defines a port (28) in communication with an interior of the housing, and a fiber optic connection module (32) including a sleeve that mounts within the port with the volume of sealant forming a seal about an exterior of the sleeve. The sleeve includes an inner end (34) adjacent the interior of the housing and an outer end (36) outside the housing. The fiber optic connection module also includes a demateable fiber optic connection interface adjacent the outer end of the sleeve. The demateable fiber optic connection interface includes a fiber optic connector. Other aspects of the present disclosure relate to fiber optic connection modules having features that make such modules suitable to be mounted within a port defined by a volume of sealant.

Abstract: A cable storage device (100) includes a removal station (110) and a storage spool (120). Slack length of the cable (190) is advanced into the cable storage device. At least a jacket (195) of the cable (190) is removed at the removal station (110). At least a signal-carrying portion of the cable (190) is wound at the storage spool (120). The removed jacket (195) exits the cable storage device (100). The cable (190) can be axially secured at the cable storage device (100). Certain types of spools can index the cable.

Abstract: A fiber optic telecommunications device includes a fiber optic cassette comprising a body defining a front and an opposite rear and an enclosed interior. A fiber optic signal entry location is defined on the body for a fiber optic signal to enter the interior via a fiber optic cable. An adapter block defines a plurality of fiber optic adapters and is removably mounted to the body with a snap-fit interlock, each adapter including a front outer end, a rear inner end, and internal structures allowing mating of optical connectors mounted to the front and rear ends, respectively. A removable spacer is mounted to the body, the spacer configured to expand the size of the enclosed interior of the cassette and a removable cover is mounted to the spacer. Connectorized optical fibers extend from the fiber optic signal entry location to the rear inner ends of at least some of the fiber optic adapters for relaying the fiber optic signal to fiber optic connectors to be coupled to the front outer ends of the adapters.

Abstract: An image capturing apparatus capable of suppressing an increase in the handling size thereof in a state in which cables are connected thereto. The image capturing apparatus is provided with a connection terminal section on a rear side of an image capturing apparatus body. The connection terminal section includes a plurality of first connector arrangement surfaces and first external connection terminals provided on the first connector arrangement surfaces, respectively. The first connector arrangement surfaces are arranged at respective locations not overlapping each other as viewed from a front-rear direction of the image capturing apparatus body and overlapping each other as viewed from a vertical direction of the image capturing apparatus body and are arranged such that the first connector arrangement surfaces face obliquely downward toward the rear of the image capturing apparatus body.

Abstract: Fiber optic modules for managing optical fibers and optical connections. In some examples, multiple modules are stackable. In some examples, the modules are configured to facilitate cable/fiber routing. Stacking elements can be used to serially stack multiple modules together. Components, such as lids and covers of the modules, can be substituted for components of different configurations. The modules and stacking elements are configured to reduce/minimize space taken up by stacking.

Abstract: A spool device (60, 90) for storing at least a portion of a telecommunications cable (800) in a storage configuration (870) includes a base (100, 600), a spool member (300, 700), and a loop engaging member (440, 740). The base (100, 600) includes a plurality of cable holders (110, 110x, 110y, 110a, 110p) configured for receiving a first portion (822, 822a, 822p) and a second portion (824, 824p) of the cable (800). The spool member (300, 700) is mounted to the base (100, 600) and includes a wrapping area (314, 714) that is configured for storing a coiled portion (826) of the cable (800). The loop engaging member (440, 740) is configured for engaging a looped portion (828) of the cable (800) and thereby secures at least the coiled portion (826) and the looped portion (828) of the cable (800). The spool device (60, 90) may be used as an adjustable overlength device for looped cable.

Abstract: An optical connection box for housing an optical connection between a distribution cable and at least one drop cable of an optical access network includes a base. The base includes a bottom configured to house an excess length of a first optical fiber of a distribution cable in a first section of the interior and configured to house an excess length of a second optical fiber of a drop cable in a second section of the interior, a first sidewall having a slot and recessed configured to receive a duct housing the distribution cable, and a plurality of splice-holder elements extending from the bottom of the base and configured to house at least one splice between the first optical fiber of the distribution cable and either (i) the second optical fiber of the drop cable, or (ii) an optical fiber pigtail that is coupled with the second optical fiber of the drop cable. The first section and the second section are disposed on opposite sides of the splice-holder elements.

Abstract: In one instance, a fiber distribution hub includes a fiber distribution cabinet and a fiber optic splitter module coupled to and disposed within the fiber distribution cabinet. The fiber optic splitter module has horizontal (perpendicular to gravity) top and bottom rails and vertically (parallel to gravity) mounted splitter assemblies. In some instances, the distribution ports are downwardly oriented to facilitate cable management. Cable management systems are also included. Other aspects are presented.