The present disclosure relates to splice enclosures adapted for providing cable repairs. The splice enclosures can include a bracket arrangement that allows for variable placement of splice modules on platforms of the bracket arrangement. The bracket arrangement can also provide cable anchoring locations.

A support frame configured to provide adapter-less fiber optic connections for fiber optic cables including a connection block configured to be fixedly coupled with a main body. A front wall of the main body includes a surface configured to abut a surface of the connection block, the connection block includes a connection port configured to receive a first fiber optic connector, and the front wall of the main body includes a connection port configured to receive a second fiber optic connector. The connection port of the connection block is configured to be aligned with the connection port of the main body such that the connection block and the main body are configured to optically couple the first fiber optic connector with the second fiber optic connector, and the connection block and the main body are configured to provide an adapter-less fiber optic connection for the first and second fiber optic connectors. The connection block may be a single piece of unitary construction.

A multi-channel parallel optical communication module includes a casing having an airtight cavity, an optical communication assembly accommodated in the airtight cavity, and a temperature controller in thermal contact with the optical communication assembly. The optical communication assembly includes a plurality of optical communication units disposed at same level, and a number of the plurality of optical communication units is greater than four.

A buffer tube for an optical fiber cable provided by the present disclosure includes an optical fiber ribbon stack, a first layer, a second layer, an optical fiber cable, a central strength member, a plurality of buffer tubes, a water blocking layer, and a sheath and plurality of rip cords. The first layer is an inner layer of the buffer tube. The first layer is made of a soft material. The soft material of the first layer is one of low smoke zero halogen, thermoplastic elastomers and thermoplastic polyurethane. The second layer is an outer layer of the buffer tube. The second layer surrounds the first layer. The second layer is made of a hard material. The hard material of the second layer is one of polypropylene, polybutylene terephthalate, and nylon.

A space saving wall mount enclosure for receiving a small number of optic fiber cassettes. The enclosure receives a rack which is rotatable about a rack axis between a first closed position wherein the cassettes are held within the enclosure and the enclosure door may be closed and a second open position where the rack is rotatable outwards allowing for the insertion or removal of the cassettes.

An optical fiber cable includes: optical fiber units each having optical fibers; a wrapping tube that wraps around the optical fiber units; a filling disposed inside the wrapping tube; and a sheath that covers the wrapping tube. The optical fiber units includes outer units that are disposed at an outermost layer of the optical fiber units. The outer units are twisted in an SZ shape around a cable central axis of the optical fiber cable. The filling is sandwiched between one of the outer units and the wrapping tube in a cross-sectional view.

An optical fiber cable including an optical fiber ribbon in a pipe, wherein the ribbon includes at least two optical fibers arranged side by side, and wherein at least two of the optical fibers are bonded intermittently along a length of the fibers.

Certain types of aggregation enclosures include cable input ports and downwardly angled cable output ports. A cover is pivotally coupled to the body so that the cover moves between an open position and a closed position. A modular component panel may be disposed within the enclosure. The component panel includes one or more distribution components (e.g., fiber distribution components or power distribution components) configured to connect at least a portion of an incoming cable to at least a portion of an outgoing cable.

Cables are constructed with extruded discontinuities in the cable jacket that allow the jacket to be torn to provide access to the cable core. The discontinuities can be longitudinally extending strips of material in the cable jacket.

Disclosed are structures and methods for active optic cable (AOC) assembly having improved thermal characteristics. In one embodiment, an AOC assembly includes a fiber optic cable having a first end attached to a connector with a thermal insert attached to the housing for dissipating heat from the connector. The AOC assembly can dissipate a suitable heat transfer rate from the active components of the connector such as dissipating a heat transfer rate of 0.75 Watts or greater from the connector. In one embodiment, the thermal insert is at least partially disposed under the boot of the connector. In another embodiment, at least one component of the connector has a plurality of fins. Other AOC assemblies may include a connector having a pull tab for dissipating heat from the assembly.