An optical distribution and splice frame system includes rack(s), enclosure(s), cable management component(s), and/or cassette(s) that have features to allow for different cable management configurations not yet available in the market. A fiber optic cassette and enclosure are designed to enable flexibility in cable management configurations for the overall system.

Disclosed are fiber optic assemblies for handling mini duplex connectors (MDC) including a rack-mountable chassis, independent sliding trays disposed in the chassis, and a plurality of MDC modules removably installable in the sliding trays. Each MDC module includes protruding features configured to interact with tray guides having corresponding features that permit vertical installation of the modules in the trays while preventing horizontal translation and rotational motion of the installed MDC modules. MDC modules may have various configuration, for instance MTP module, patching module and pre-terminated tailed module configurations. The assemblies and components disclosed herein maximize connections densities of MDC connectors while improving access thereto in high density applications.

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.

A multi-core/single-core conversion module is disclosed. The multi-core/single-core conversion module includes a housing including a first end, a second end and a lateral wall defining an inner space between the first end and the second end, a first adapter attached to the first end of the housing, two or more second adapters attached to the second end of the housing, a multi-core optical connector inserted into the first adapter from the inner space of the housing, a plurality of single-core optical connectors respectively inserted into the second adapters from the inner space of the housing, and a plurality of optical fibers connecting the multi-core optical connector to the plurality of single-core optical connectors with each other. The second adapters are arranged on the second end across a plurality of tiers. An opening can be formed by a part of the lateral wall being detached.

A latch mechanism for retaining a tray in a selected one of a first, second position and third position. The latch mechanism comprises notches arranged on an inner surface of the housing along an axis parallel to a direction of travel of the tray, an elongate actuator on the tray and opposite the inner surface, the actuator comprising a first elongate member and a second elongate member, an inner end of the first elongate member connected to an inner end of the second elongate member at a connection point, a stop positioned at the connection point wherein the stop is biased laterally towards the inner surface. By increasing a distance between an outer end of the first elongate member and an outer end of the second elongate member the stop is moveable from an unactuated state wherein the stop is engageable by a selected one of the notches and such that the tray is retainable in a selected one of the first, second and third position, to an actuated state wherein the stop moves laterally against the biasing force away from the inner surface and such that the stop is no longer engageable by one of the notches.

A fiber optic system includes a telecommunications chassis defining a front and a rear, a plurality of blades slidably mounted to the chassis, the blades slidable in a direction extending from the front to the rear, and a plurality of fiber optic cassettes removably mounted to each blade. Each fiber optic cassette includes a housing defining a maximum cassette height, the housing formed by a base and a cover mounted thereon. Each cassette defines fiber optic connection locations. The base of each cassette defines a notched area for receiving a portion of the blade on which the cassette is mounted such that the blade does not increase the overall maximum height defined by the housing.

An apparatus forms a module. The apparatus includes a housing configured to load the module through a front end of a panel. The apparatus includes a connector cluster. The apparatus includes a set of tabs corresponding to a set of securing members that secure the module to a panel.

A termination field and a guide member are independently pivotally coupled to a base body. The termination field pivots relative to the base body along a path of travel. The guide member is coupled to the base body to provide bend radius protection to cables plugged into the termination field. The guide member defines a channel leading the cables from the termination field towards a first side of the base body at an exterior of the base body. In certain examples, the guide member and termination field pivot relative to the base body about different hinge axes. In other examples, the termination field pivots with the guide member for part of the path of travel and relative to the guide member for another part of the path of travel.

A hybrid chassis for fiber management includes a fixed tray adapted to mount to one of a rack and a frame; a sliding chassis assembly housed in the fixed tray; fiber connectors on a front faceplate of the sliding chassis assembly; internal cross connections in the sliding chassis assembly between the fiber connectors; and a sliding mechanism between the sliding chassis assembly and the fixed tray providing constrained sliding of the sliding chassis assembly between at least two positions including an operating, recessed position and a maintenance, fiber access position. In the operating, recessed position, the sliding chassis assembly can be recessed by about 3.3″ in the fixed tray, wherein, in the maintenance, fiber access position, the sliding chassis assembly can be recessed by about 1.3″ for fiber access, and wherein the constrained sliding can be about 2″.

A fiber distribution device includes a swing frame chassis pivotally mounted to a support structure. At least a first optical splitter module is mounted to the swing frame chassis. Pigtails having connectorized ends are carried by the swing frame chassis and have portions that are routed generally vertically on the swing frame chassis. An optical termination field includes fiber optic adapters carried by the swing frame chassis. The fiber optic adapters are configured to receive the connectorized ends of the pigtails.