Abstract: Fiber optic equipment guides and rails and related methods are disclosed. In one embodiment, the fiber optic equipment guides and rails have at least one stopping member disposed therein to provide at least one stopping position during movement. The fiber optic equipment guides and rails can be included in fiber optic equipment to support movement or translation of the fiber optic equipment for access. Such fiber optic equipment can include, but is not limited to, fiber optic equipment chassis, drawers, equipment trays, and fiber optic modules. The fiber optic equipment guides and/or rails include at least one stopping member configured to provide at least one stopping position during movement. Stopping positions allow fiber optic equipment to be retained in a given position during access to the fiber optic equipment. The stopping positions are configured to be overcome with additional force to allow further movement of the fiber optic equipment.

Abstract: A cable routing guide having an arm with a first end and a second end is disclosed. The arm is adapted to attach the cable routing guide to a structure at the first end. A guide piece attaches to the arm at the second end. The guide piece has sides that enclose a passage adapted to receive at least one cable. The sides are concave, bowing toward the passage. The retainer is configured to maintain the at least one cable within the passage until the at least one cable is intentionally removed. The retainer has a retainer clip and/or a slot that allows the at least one cable to be received by the guide piece and to remain maintained within the guide piece until the at least one cable is intentionally removed. The slot may be at an angle to the longitudinal axis of the at least one cable. Additionally, the slot may be curvilinear or v-shaped. An attachment bracket connects to the first end of the arm. The attachment bracket may be connected at an angle to the longitudinal axis of the arm.

Abstract: An optical fiber distribution enclosure includes a housing defining an interior, a first fiber distribution area disposed within an upper portion of the interior, a second fiber distribution area disposed within a lower portion of the interior and a signal splitting area disposed between the fiber distribution areas. A splitter module secured within the signal splitting area has a connectorized splitter input optical fiber and connectorized splitter output optical fibers. A fiber parking area is movably disposed within the lower portion adjacent the second fiber distribution area for temporarily storing splitter output optical fibers that are not routed to the fiber distribution areas. An input fiber distribution area disposed within the interior interconnects an optical fiber of a feeder cable with the splitter input optical fiber. The splitter output optical fibers are eventually routed to a fiber distribution area and interconnected with a corresponding optical fiber of a distribution cable.

Abstract: Fiber optic equipment guides and rails and related methods are disclosed. In one embodiment, the fiber optic equipment guides and rails have at least one stopping member disposed therein to provide at least one stopping position during movement. The fiber optic equipment guides and rails can be included in fiber optic equipment to support movement or translation of the fiber optic equipment for access. Such fiber optic equipment can include, but is not limited to, fiber optic equipment chassis, drawers, equipment trays, and fiber optic modules. The fiber optic equipment guides and/or rails include at least one stopping member configured to provide at least one stopping position during movement. Stopping positions allow fiber optic equipment to be retained in a given position during access to the fiber optic equipment. The stopping positions are configured to be overcome with additional force to allow further movement of the fiber optic equipment.

Abstract: Embodiments disclosed in the detailed description include fiber optic panels and related apparatuses configured to retain fiber optic components for establishing fiber optic connections. The fiber optic panels are configured such that the fiber optic components and any fiber optic connections made to the fiber optic components can be retained along a depth axis in a depth space of a chassis when the fiber optic panel is inserted into the chassis. The longitudinal axes of the fiber optic components are not parallel to the depth axis of the chassis. In this manner, the area of the depth space of the chassis is utilized to retain fiber optic components so that a greater density of fiber optic components can be supported by fiber optic panels for a given length of the chassis. The fiber optic panel may be any type of fiber optic patch panel or fiber optic module.

Abstract: An optical fiber distribution enclosure includes a housing defining an interior, a first fiber distribution area disposed within an upper portion of the interior, a second fiber distribution area disposed within a lower portion of the interior and a signal splitting area disposed between the fiber distribution areas. A splitter module secured within the signal splitting area has a connectorized splitter input optical fiber and connectorized splitter output optical fibers. A fiber parking area is movably disposed within the lower portion adjacent the second fiber distribution area for temporarily storing splitter output optical fibers that are not routed to the fiber distribution areas. An input fiber distribution area disposed within the interior interconnects an optical fiber of a feeder cable with the splitter input optical fiber. The splitter output optical fibers are eventually routed to a fiber distribution area and interconnected with a corresponding optical fiber of a distribution cable.

Abstract: An optical fiber distribution enclosure includes a housing defining an interior, a first fiber distribution area disposed within an upper portion of the interior, a second fiber distribution area disposed within a lower portion of the interior and a signal splitting area disposed between the fiber distribution areas. A splitter module secured within the signal splitting area has a connectorized splitter input optical fiber and connectorized splitter output optical fibers. A fiber parking area is movably disposed within the lower portion adjacent the second fiber distribution area for temporarily storing splitter output optical fibers that are not routed to the fiber distribution areas. An input fiber distribution area disposed within the interior interconnects an optical fiber of a feeder cable with the splitter input optical fiber. The splitter output optical fibers are eventually routed to a fiber distribution area and interconnected with a corresponding optical fiber of a distribution cable.

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.