Distribution frame

Abstract: A fiber optic telecommunications frame is provided including rotatable panels having front and rear termination locations, the panels positioned on left and right sides of the frame. The frame includes vertical access for the rear cables, and rear cable guides disposed within the frame. The frame further includes left and right vertical cable guides for patch cables. The frame further includes cable storage spools for the patch cables positioned adjacent to the left and right panels of the frame. The frame includes a horizontal passage linking the left and right panels and the cable guides. A lower portion of the frame defines splice tray holders and a central passage from the splice tray holders to the rear sides of the left and right panels. From a front of each panel, access to a rear of the panel is provided by the hinged panels.

Abstract: Disclosed is an optical fiber distribution frame which comprises trays including panels of optical connectors. Each tray is slidably mounted in the frame and can be pivoted downward to provide front access to the fibers and connectors in 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. An alternative embodiment includes an Interbay Fiber Manager (IFM) for routing and storing additional jumpers.

Abstract: The invention is embodied in a distributed intelligence optical fiber communications system capable of fully automated and continuous monitoring and testing of the optical fibers and their connections within the optical fiber distribution frames therein. In particular, it is an optical communications system having an optical distribution frame including interconnection modules having actively intelligent microcontrollers thereon. Also, the distribution frame includes inventive electrical and optical interconnection fabrics between the distributed intelligence located on the interconnection modules and a host located outside of the distribution frame. The distributed intelligence interconnection modules allow monitoring, testing and/or related activities of the overall optical communications system to be performed locally at the interconnection modules. Also, when used in combination with the electrical and optical interconnection fabrics, the inventive modules substantially reduce optical fiber routing and enable more effective monitoring and testing operations to be performed, while maintaining compatibility with existing conventional cross-connect, switching and network architectures.