A sealing system for a telecommunication closure includes an endcap having a plurality of slotted areas defined therein; and a plurality of sealing segment assemblies mounted to the endcap that when combined form a substantially continuous sealing perimeter around the endcap. Each sealing segment assembly is disposed in one of the plurality of slotted areas and includes an inner segment and an outer segment that when mated together are configured to seal at least one cable routed through a cable port opening.

A butt closure base includes a base housing defining a plurality of cavities. A first gel is disposed in each of the plurality of cavities. The butt closure base further includes a plurality of wedge assemblies, each of the plurality of wedge assemblies removably insertable into one of the plurality of cavities. Each of the plurality of wedge assemblies includes an outer cover, a second gel, and a main pressure plate in contact with the second gel. The main pressure plate is movable along a longitudinal axis to apply pressure to the second gel. Each of the plurality of wedge assemblies further includes a latch assembly. The latch assembly includes an adjustable tab and a stop member movable between a first position which limits movement of the adjustable tab and a second position in which movement of the adjustable tab is not limited by the stop member.

A telecommunications component includes an outer housing that includes a badge holder. The badge holder is configured to receive a badge. The badge is configured to be inserted into the badge holder. The badge includes a feature that is identifying of the source of the telecommunications component and the feature is at least one of a logo, a specific color, text information, a barcode, a QR code, and a RFID tag. The badge includes a pair of arms extending from opposing sides to engage with the badge holder of outer housing. The badge includes a securing feature that is configured to secure the badge within the badge holder.

The present disclosure relates to a housing having an interior and an exterior. The housing includes a first housing piece and a second housing piece that are coupled together by a joint. The joint includes a bonding material and the joint is configured such that when the bonding material is pressurized during formation of the joint the bonding material is predisposed to move toward the interior of the housing as compared to the exterior of the housing.

An optical fiber management tray, such as a splice tray, and related assemblies. The tray includes fiber guiding features for improved routing of reliable ribbon fiber on the tray. In some embodiments, a fiber management tray is configured to receive a routed fiber ribbon and a plurality of routed individual optical fibers, the tray being further configured to support a plurality of individual fiber splices that splice the fibers of the ribbon fiber to the individual fibers.

A cable enclosure including a main portion, a multi-cable terminal secured to the main portion, and a sealing assembly for accommodating at least one cable portion and for providing a watertight seal between the sealing assembly and the at least one cable portion and between the sealing assembly and the main portion.

A sealed terminal has a housing, a splice tray, and a faceplate. The housing has an interior compartment and a first perimeter flange defining an opening into the interior compartment. The splice tray is positioned in the interior compartment and is configured to support a module or a cartridge. The faceplate has a plurality of ports and a second perimeter flange extending at a perimeter edge of the faceplate. The sealed terminal also has at least one connection bracket and a gasket for connecting the housing and the faceplate to each other. The connection bracket has a slot receiving the first perimeter flange and the second flange in an abutting position. The gasket is positioned between the first perimeter flange and the second perimeter flange and configured to seal any gap therebetween.

A telecommunications enclosure is disclosed. In one example, the telecommunications enclosure includes an upper dome and a lower base. An O-ring seal can be compressed between a sealing surface of the upper dome and/or a sealing surface of the lower base to provide sealing thereinbetween.

A cabinet unit for use in an optical fiber distribution system may include a housing having a cavity, a plurality of extension portions contained within the housing, each extension portion being adapted to support an adapter for receiving cables aligned lengthwise with the extension portion, and a support structure formed on an inner surface of the housing, each extension portion being mounted to the housing by the support structure and extends away from the inner surface of the housing. The plurality of extension portions may be hingedly coupled to the support structure. A clearance between two adjacent extension portions of a given support bar may be configured to be adjusted by rotating the adjacent extension portions along their respective hinged connections.

A device for sealing a telecommunications cable is disclosed. The device includes a first part, and a second part having one or more attachment members that assemble onto the first part to assemble the first and second parts together. A cavity is defined between the first and second parts that extends along a central axis and between first and second ends of the device. The cavity is structured to seal the cable between the first and second parts without threading the cable through the first and second ends, and the first and second parts define at least one mounting location for a cable port in a telecommunications enclosure. The cavity may receive a resin to seal the cable between the first and second parts.