Abstract: Fiber optic drawers supporting fiber optic modules are disclosed. The drawer is movable about a chassis. At least one fiber optic equipment tray is received in the drawer. The fiber optic equipment tray(s) is movable about the drawer and configured to receive at least one fiber optic module. The fiber optic module(s) is movable about a fiber optic equipment tray. In this manner, enhanced access can be provided to the fiber optic module(s) and their fiber optic connections. The drawer can moved out from the chassis to provide access to fiber optic equipment tray(s) and fiber optic module(s). The fiber optic equipment tray(s) can be moved out from the drawer to provide enhanced access to fiber optic module(s). The fiber optic module(s) can be moved from fiber optic equipment tray(s) to provide further enhanced access to fiber optic module(s). The drawer may also be tiltable about the chassis.

Abstract: A cable routing guide attached to a fiber optic apparatus, such as a module positioned on a fiber optic equipment tray is disclosed. The cable routing guide is adapted to receive a length of at least one fiber optic cable intended to be connected to a cable connection point, such as a fiber optic adapter disposed on the module. The cable routing guide allows the at least one fiber optic cable to move in response to the fiber optic equipment tray or the module moving between a first position and a second position in a manner such that the length of the at least one fiber optic cable from the cable routing guide to the fiber optic adapter remains substantially unchanged. Moreover, the at least one fiber optic cable that is received by the cable routing guide may be retained and maintained by the cable routing guide without being tensed or stressed.

Abstract: Fiber optic drawers supporting fiber optic modules are disclosed. The drawer is movable about a chassis. At least one fiber optic equipment tray is received in the drawer. The fiber optic equipment tray(s) is movable about the drawer and configured to receive at least one fiber optic module. The fiber optic module(s) is movable about a fiber optic equipment tray. In this manner, enhanced access can be provided to the fiber optic module(s) and their fiber optic connections. The drawer can moved out from the chassis to provide access to fiber optic equipment tray(s) and fiber optic module(s). The fiber optic equipment tray(s) can be moved out from the drawer to provide enhanced access to fiber optic module(s). The fiber optic module(s) can be moved from fiber optic equipment tray(s) to provide further enhanced access to fiber optic module(s). The drawer may also be tiltable about the chassis.

Abstract: A cable routing guide attached to a fiber optic apparatus, such as a module positioned on a fiber optic equipment tray is disclosed. The cable routing guide is adapted to receive a length of at least one fiber optic cable intended to be connected to a cable connection point, such as a fiber optic adapter disposed on the module. The cable routing guide allows the at least one fiber optic cable to move in response to the fiber optic equipment tray or the module moving between a first position and a second position in a manner such that the length of the at least one fiber optic cable from the cable routing guide to the fiber optic adapter remains substantially unchanged. Moreover, the at least one fiber optic cable that is received by the cable routing guide may be retained and maintained by the cable routing guide without being tensed or stressed.

Abstract: A high density fiber optic distribution frame includes a frame assembly, one or more left-hand connector module housings mounted on the frame assembly, one or more right-hand connector module housings mounted on the frame assembly and an Interbay Storage Unit (IBU) positioned on the frame assembly medially between the left-hand connector module housings and the right-hand connector module housings. Each connector module housing includes one or more connector modules having one or more adapters for interconnecting optical fibers between connector modules on the distribution frame or on an adjacent distribution frame in a communications network. The distribution frame is compatible with existing fiber optic connector housings, maintains the minimum bend radius of the optical fibers transitioned on the frame between connector modules, and reduces the length of a single length jumper employed on the frame.

Abstract: A high density fiber optic distribution frame includes a frame assembly, one or more left-hand connector module housings mounted on the frame assembly, one or more right-hand connector module housings mounted on the frame assembly and an Interbay Storage Unit (IBU) positioned on the frame assembly medially between the left-hand connector module housings and the right-hand connector module housings. Each connector module housing includes one or more connector modules having one or more adapters for interconnecting optical fibers between connector modules on the distribution frame or on an adjacent distribution frame in a communications network. The distribution frame is compatible with existing fiber optic connector housings, maintains the minimum bend radius of the optical fibers transitioned on the frame between connector modules, and reduces the length of a single length jumper employed on the frame.

Abstract: A high density fiber optic distribution frame includes a frame assembly, one or more left-hand connector module housings mounted on the frame assembly, one or more right-hand connector module housings mounted on the frame assembly and an Interbay Storage Unit (IBU) positioned on the frame assembly medially between the left-hand connector module housings and the right-hand connector module housings. Each connector module housing includes a mounting frame and at least one connector module having at least one fiber optic adapter for interconnecting optical fibers between connector modules on the distribution frame. The connector module is movable between a stowed position wherein the fiber optic adapter is not accessible and a deployed position wherein the fiber optic adapter is accessible. The distribution frame maintains the minimum bend radius of the optical fiber transitioned between connector modules, and reduces the length of a single length jumper employed on the frame.

Abstract: A high density fiber optic distribution frame includes a frame assembly, one or more left-hand connector module housings mounted on the frame assembly, one or more right-hand connector module housings mounted on the frame assembly and an Interbay Storage Unit (IBU) positioned on the frame assembly medially between the left-hand connector module housings and the right-hand connector module housings. Each connector module housing includes a mounting frame and at least one connector module having at least one fiber optic adapter for interconnecting optical fibers between connector modules on the distribution frame. The connector module is movable between a stowed position wherein the fiber optic adapter is not accessible and a deployed position wherein the fiber optic adapter is accessible. The distribution frame maintains the minimum bend radius of the optical fiber transitioned between connector modules, and reduces the length of a single length jumper employed on the frame.

Abstract: A high density fiber optic distribution frame includes a frame assembly, one or more left-hand connector module housings mounted on the frame assembly, one or more right-hand connector module housings mounted on the frame assembly and an Interbay Storage Unit (IBU) positioned on the frame assembly medially between the left-hand connector module housings and the right-hand connector module housings. Each connector module housing includes one or more connector modules having one or more adapters for interconnecting optical fibers between connector modules on the distribution frame or on an adjacent distribution frame in a communications network. The distribution frame is compatible with existing fiber optic connector housings, maintains the minimum bend radius of the optical fibers transitioned on the frame between connector modules, and reduces the length of a single length jumper employed on the frame.

Abstract: A distribution frame includes a plurality of vertically stacked equipment housings arranged in columns and an Interbay Storage Unit medially disposed in a center section between the columns. The Interbay Storage Unit includes a base and a plurality of storage hubs vertically spaced on the base. The housings are angled downwardly in the direction of the center section and the base of the Interbay Storage Unit includes reduced width sections between adjacent storage hubs that increase the space available between the Interbay Storage Unit and the housings for routing excess lengths of jumper cables. Fingers are laterally spaced about each storage hub and a plurality of routing guides are staggered on the housings to separate jumper cables routed between the housings to interconnect service and subscriber transmission lines adjacent the base of the distribution frame where the excess lengths of the jumper cables accumulate.

Abstract: A corner wall-mount fiber optic connector housing includes an enclosure having a back plate for mounting in a corner between two walls. The enclosure is provided with at least one provider port for entry of a fiber optic provider cable having a plurality of optical fibers and at least two customer ports for entry of a fiber optic customer cable having a plurality of optical fibers. At least two fiber optic connector panel mounts located within the enclosure have an aperture for receiving a plurality of connectors to optically interconnect the fibers of the provider cable with the fibers of the customer cable. The back plate is formed in two planes at an angle to each other for mounting in the corner, and one of the customer ports and one of the connector panel mounts is positioned adjacent a respective one of the two planes of the back plate.

Abstract: A mixed media outlet is provided that is capable of being mounted upon a wall and that includes ports that are typically designed to provide separate access to an electrical network and to an optical network. The wall mounted outlet can therefore permit a telephone to be connected to the electrical network, and a computer to be connected to the optical network. Alternatively, the outlet can permit a telephone to also be connected to either the same or a different optical network than the computer. The mixed media outlet includes a housing adapted to be wall mounted and first and second ports that are disposed within openings defined by the housing, such as a data port and a voice port.

Abstract: A corner wall-mount fiber optic connector housing includes an enclosure having a back plate for mounting in a corner between two walls. The enclosure is provided with at least one provider port for entry of a fiber optic provider cable having a plurality of optical fibers and at least two customer ports for entry of a fiber optic customer cable having a plurality of optical fibers. At least two fiber optic connector panel mounts located within the enclosure have an aperture for receiving a plurality of connectors to optically interconnect the fibers of the provider cable with the fibers of the customer cable. The back plate is formed in two planes at an angle to each other for mounting in the corner, and one of the customer ports and one of the connector panel mounts is positioned adjacent a respective one of the two planes of the back plate.

Abstract: A strain relief bracket for use in conventional and modular furniture applications guards against excessive bending of copper and fiber optic cable. The device is a substantially rigid durable bracket that has an adhesive surface for adhesion to the interior of a furniture wall. The device is bi-planar, having a first section in a first plane, a raised flange section in a second plane, and a second section connecting the first section and raised flange section. A flange at the end of the first section secures the bracket to the edge of an opening in the furniture wall. Cables are secured to the bracket by cable ties that extend through holes provided on the raised flange section. The bi-planar arrangement of the bracket minimizes the bend radius of the cables and thereby strain relieves the cable, adapters, and connectors in the wall.

Abstract: A wall mount cabinet is provided that has a front door that pivots downward and a side door that pivots out to the side. The side door is latched to the front door such that opening of the front door also opens the side door.