A thermal management system for a power and fiber splice enclosure that includes a housing including electrical components is provided. The thermal management system includes a solar shield disposed external to the housing and covering at least a major portion of the housing. The thermal management system includes a vent disposed in the housing for venting hot air from the enclosure. The thermal management system includes a condenser thermally coupled to a heat conducting component of the enclosure for cooling at least the heat conducting component

A communication enclosure includes a housing and a fiber optic organizer. The housing defines a plurality of ports. The fiber optic organizer includes a tower configured to hold one or more fiber management trays. The tower is mountable to the housing in one of at least two different tower positions. In the first tower position, the tower is disposed between a first of the ports and a second of the ports. In the second tower position, the tower is disposed between the second port and a third of the ports.

A telecommunications closure including a closure body defining an interior. An organizer is located within the interior of the closure body. The organizer including a base, a cable seal, a cable management device, and a mounting interface; wherein the mounting interface includes a mating interface including a plurality of mating shapes which interface with one another. The mating shapes include at least one lower protrusion and a recess, wherein the recess is larger than the lower protrusion, and at least one mounting tab. The mating shapes can include V-shapes.

A telecommunications closure includes a base interface (10) for supporting the closure (60) during assembly, or repair, or later servicing, or installation, or as a permanent mount. The base interface (10) includes structure for mounting to cables, structure for mounting to elements for connecting to the interior elements of the closure (60), and elements for mounting to an interface support. A support device can be used as a workstand, a lift device, a pole mount, a wall mount or another mounting system.

An optical termination module (50) comprises a fixed part (60) to be attached to a mounting member (108) of an electric cabinet (100) and a movable part (70) rotatably attached to the fixed part (60) to move relative to the fixed part (60) about a rotation axis (X-X) between a first position and a second position. The fixed part (60) has a bottom surface (61a) with an inlet opening (61b) configured to receive an optical drop cable (1) and the movable part (70) has a bottom surface (71a) with one or more outlet openings (71b) configured to receive respective one or more optical customer cables (5).

Grounding assemblies for cables entering telecommunications enclosures. The grounding assemblies include a cable fixation subassembly and a grounding subassembly that are electrically coupled together to ground strength members and a conductive shield of a cable. The cable fixation subassembly can fixate the cable such that the strength members lie in a plane that is at a non-zero angle relative to each of a horizontal reference plane and a vertical reference plane.

A fiber optic splice enclosure includes a basket. The basket includes an outer shell, the outer shell including an outer sidewall defining at least a portion of a periphery of the basket. The basket further includes an insert disposed within the outer shell, the insert including a first sidewall and a second sidewall spaced apart from each other along a transverse axis and each extending along a longitudinal axis to define an inner channel therebetween. The first sidewall and the second sidewall are each further spaced apart from the outer sidewall along the longitudinal axis to define a first outer channel and a second outer channel. The fiber optic splice enclosure further includes a splice tray assembly including at least one splice tray, the splice tray assembly disposed within the inner channel.

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.

A fiber distribution hub includes a module mounting location disposed within the cabinet separate from a termination field. The module mounting location includes a plurality of spaces at which various types of modules can be mounted. For example, splitter modules, connector storage modules, and/or fiber storage modules can be installed at the module mounting location. The modules can be mounted in any order or configuration. Some of the modules may be tethered together before installation at the hub.

A closure includes a cover and seal block. A feeder cable pathway and rear cover is provided for separation of feeder cables from drop cables. The organizer in the closure includes an end cap and rear cable storage. Cable fixation clips, linear or bendable, can be used individually or daisy chained together. Cable fixation chambers are positioned on top of the gel block housing. The organizer is a click together organizer. Dual heights on cable guides on sides of the groove plate facilitate cable installation. Tray supports with rounded ends prevent looseness of the tray mounts. Other organizers include cable routing features for compact storage.