The present disclosure relates to features of a telecommunication enclosure. Example features can include mounting plate attachment features, housing latching features, housing hinge features and fiber routing features.

Fiber optic splice closures adapted to house a large number of fiber splices. The closure holds a splice assembly including a support frame that supports two stacks of splice trays. The splice assembly can be inverted to access the second stack of splice trays. The support frame can also define one or more fiber organizing areas within the splice closure.

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.

A connector closure for fiber optical cables includes a base portion having first and second compartments. One of the first and second compartments is designed to have a cover or door that allow selective access, while the other compartment signed for only authorized access. The connector closure features universal mounting arrangements, e.g., aerial, surface/wall, pedestal, or vault arrangements. Further, the closure may incorporate a splice enclosure.

An enclosure (10) includes a base (38) defining a splice region (148) and a cover (40) coupled to the base (38) to move between a closed position and an open position. A plurality of ruggedized adapters (26) are on the cover (40), each adapter having an inner port (64) and an outer port (66). A removable module (32) is disposed on the cover (40), at least one input fiber (12) being routed from the splice region (148) of the base (38) to the removable module (32), wherein the at least one input fiber (12) is output from the module as a pigtail (28) having a connectorized end that is connected to an inner port (64) of a ruggedized adapter (26). A cable input location (16) receives an input cable (14/20) including at least one tube (138) surrounding at least one fiber (12) that carries the same signal as the at least one input fiber (12) being routed from the splice region (148) to the removable module (32). The input cable (14/20) is anchored to the base (38) at the cable input location (16). A tube holder (150) is slidably mounted to the base (38) past the cable input location (16), wherein the tube holder (150) keeps separate an unused fiber-carrying tube (138) that is stored within the base (38) in a loop (122) from a fiber-carrying tube (138) whose fiber (12) leads toward the splice region (148) of the base (38) for further routing toward the removable module (32).

Aspects of the present disclosure relate to selectable and interchangeable covers, frames, and lids for a plurality of different telecommunications module frames. The selectable covers can vary, for example, with respect to size, shape, and number arrangement, and configuration of ports to provide for different selectable combinations of module assemblies.

An enclosure (10) includes a base (38) defining a splice region (148) and a cover (40) coupled to the base (38) to move between a closed position and an open position. A plurality of ruggedized adapters (26) are on the cover (40), each adapter having an inner port (64) and an outer port (66). A removable module (32) is disposed on the cover (40), at least one input fiber (12) being routed from the splice region (148) of the base (38) to the removable module (32), wherein the at least one input fiber (12) is output from the module as a pigtail (28) having a connectorized end that is connected to an inner port (64) of a ruggedized adapter (26). A cable input location (16) receives an input cable (14/20) including at least one tube (138) surrounding at least one fiber (12) that carries the same signal as the at least one input fiber (12) being routed from the splice region (148) to the removable module (32). The input cable (14/20) is anchored to the base (38) at the cable input location (16). A tube holder (150) is slidably mounted to the base (38) past the cable input location (16), wherein the tube holder (150) keeps separate an unused fiber-carrying tube (138) that is stored within the base (38) in a loop (122) from a fiber-carrying tube (138) whose fiber (12) leads toward the splice region (148) of the base (38) for further routing toward the removable module (32).

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.

The present disclosure relates to a telecommunications enclosure haying cable ports and an internal optical tapping or indexing architecture. The cable ports can be defined by hardened fiber optic adapters.

Fiber optic splice closures adapted to house a large number of fiber splices. The closure holds a splice assembly including a support frame that supports two stacks of splice trays. The splice assembly can be inverted to access the second stack of splice trays. The support frame can also define one or more fiber organizing areas within the splice closure.