Abstract: Fiber optic housings configured to accommodate fiber optic modules/cassettes and fiber optic panels are disclosed. In one embodiment, a fiber optic apparatus is provided and comprised of a fiber optic housing and one or more removable panel clips. Each of the one or more removable panel clips includes at least one receptacle configured to receive an insert of a fiber optic panel to support the fiber optic panel in the fiber optic housing. In another embodiment, a fiber optic shelf configured to be supported in a fiber optic housing is provided. The fiber optic shelf comprises a mounting surface and one or more removable panel clips attached to the mounting surface that each includes at least one receptacle configured to receive an insert of a fiber optic panel to support the fiber optic panel in the mounting surface. Related components and methods are also disclosed.

Abstract: A support shelf for fiber optic hardware is disclosed. Generally, the support shelf includes a plurality of component mounting features that permits releasably mounting of fiber optic hardware at a plurality of locations on the support shelf. The component mounting features are generally openings in a base of the support shelf and may be slots in the base as well. With this improved configuration, fiber optic hardware such as adapter panels can be mounted at a variety of locations on the support shelf ranging from flush with a front edge of the support shelf to a recessed mounting, which is a distance from the front edge.

Abstract: A rotatable routing guide assembly for fiber optic cables routed in a fiber optic equipment shelf is disclosed. The assembly comprises a guide portion, an attachment feature and a keyed receiver. The guide portion has a bottom, a top, a deformable first wall, a deformable second wall and a third wall forming a plurality of segments, and is configured to receive fiber optic cables of different sizes by different ones of the plurality of segments. The attachment feature removably attaches the guide portion to the shelf. The attachment feature has a first tab forming a first notch with the guide portion, and a second tab forming a second notch with the guide portion. The keyed receiver is located in the shelf and has a lip extending partially around an interior edge. The lip is received in at least one of the first notch and the second notch and friction fit between at least one of the first tab and the second tab and the guide portion.

Abstract: A fiber optic strain relief device is provided. The device has a base that attaches to a piece of equipment and/or hardware. A length of strap positions in the base and forms a loop. The loop is adapted to at least partially encircle a portion of a cable positioned at the base. A strap tightener incrementally shortens the length of the strap, reducing the loop and tightening the strap around the cable. The strap tightener may be a ratchet assembly comprising an actuator, a ratchet cap, a pin, a ratchet lock and a release. The length of strap inserts into a slot in the pin. The ratchet assembly operates to tighten the length of strap encircling the portion of the cable by incrementally rotating the pin. The release allows the strap to be loosened around the fiber optic cable.

Abstract: Fiber optic housings configured to accommodate fiber optic modules/cassettes and fiber optic panels are disclosed. In one embodiment, a fiber optic apparatus is provided and comprised of a fiber optic housing and one or more removable panel clips. Each of the one or more removable panel clips includes at least one receptacle configured to receive an insert of a fiber optic panel to support the fiber optic panel in the fiber optic housing. In another embodiment, a fiber optic shelf configured to be supported in a fiber optic housing is provided. The fiber optic shelf comprises a mounting surface and one or more removable panel clips attached to the mounting surface that each includes at least one receptacle configured to receive an insert of a fiber optic panel to support the fiber optic panel in the mounting surface. Related components and methods are also disclosed.

Abstract: Stackable shelves for a fiber optic housing and related components and methods are disclosed. In one embodiment, a stackable shelf for a fiber optic housing is provided. The stackable shelf comprises a mounting surface and one or more stacker assemblies stacked above the mounting surface, each configured to support fiber optic equipment in one or more height spaces. The one or more stacker assemblies are further configured to support one or more additional removable stacker assemblies each configured to support fiber optic equipment at one or more additional height spaces. In another embodiment, a removable stacker assembly configured to support fiber optic equipment in a stackable shelf is provided. Related methods are also disclosed.

Abstract: A rotatable routing guide assembly for fiber optic cables routed in a fiber optic equipment shelf is disclosed. The assembly comprises a guide portion, an attachment feature and a keyed receiver. The guide portion has a bottom, a top, a deformable first wall, a deformable second wall and a third wall forming a plurality of segments, and is configured to receive fiber optic cables of different sizes by different ones of the plurality of segments. The attachment feature removably attaches the guide portion to the shelf. The attachment feature has a first tab forming a first notch with the guide portion, and a second tab forming a second notch with the guide portion. The keyed receiver is located in the shelf and has a lip extending partially around an interior edge. The lip is received in at least one of the first notch and the second notch and friction fit between at least one of the first tab and the second tab and the guide portion.

Abstract: A support shelf for fiber optic hardware is disclosed. Generally, the support shelf includes a plurality of component mounting features that permits releasably mounting of fiber optic hardware at a plurality of locations on the support shelf. The component mounting features are generally openings in a base of the support shelf and may be slots in the base as well. With this improved configuration, fiber optic hardware such as adapter panels can be mounted at a variety of locations on the support shelf ranging from flush with a front edge of the support shelf to a recessed mounting, which is a distance from the front edge.

Abstract: Mounting clips and fiber optic equipment and apparatuses that include one or more mounting clips for mounting fiber optic equipment and related methods are disclosed. The mounting clips allow fiber optic equipment to be easily installed or mounted for storage, such as in, for example, fiber optic equipment racks or cabinets. In one embodiment, a fiber optic apparatus is provided comprising a housing and at least one optical component supported in the housing. At least one mounting clip is attached to at least one side of the housing of the fiber optic equipment. The mounting clip is configured to receive at least one mounting bracket configured to be installed on a fiber optic equipment rack. In this manner, when the mounting clip is received or attached to the mounting bracket, the housing of the fiber optic equipment is secured to the fiber optic equipment rack.

Abstract: A fiber optic strain relief device is provided. The device has a base that attaches to a piece of equipment and/or hardware. A length of strap positions in the base and forms a loop. The loop is adapted to at least partially encircle a portion of a cable positioned at the base. A strap tightener incrementally shortens the length of the strap, reducing the loop and tightening the strap around the cable. The strap tightener may be a ratchet assembly comprising an actuator, a ratchet cap, a pin, a ratchet lock and a release. The length of strap inserts into a slot in the pin. The ratchet assembly operates to tighten the length of strap encircling the portion of the cable by incrementally rotating the pin. The release allows the strap to be loosened around the fiber optic cable.

Abstract: Adapter modules, housing assemblies that house the adapter modules, and frame assemblies that contain the housing assemblies are disclosed that are all relatively compact and support a relatively high density of components. The modules, assemblies and frames have configurations that take advantage of bend-insensitive cable fibers and jumper fibers. The adapter module is a cassette-like case that allows for a length of cable fiber to be wound tightly therein in a substantially circular loop configuration when closed. The housing assembly houses a plurality of adapter modules and is configured so that the cable and jumper fibers have relatively tight bends within the housing interior. The frame assembly is configured to support a plurality of stacked housing assemblies and to route the jumper fibers through routing conduits and/or routing troughs so that the jumper fibers are enclosed within the frame assembly rather than dangling outside of the frame.

Abstract: Adapter modules, housing assemblies that house the adapter modules, and frame assemblies that contain the housing assemblies are disclosed that are all relatively compact and support a relatively high density of components. The modules, assemblies and frames have configurations that take advantage of bend-insensitive cable fibers and jumper fibers. The adapter module is a cassette-like case that allows for a length of cable fiber to be wound tightly therein in a substantially circular loop configuration when closed. The housing assembly houses a plurality of adapter modules and is configured so that the cable and jumper fibers have relatively tight bends within the housing interior. The frame assembly is configured to support a plurality of stacked housing assemblies and to route the jumper fibers through routing conduits and/or routing troughs so that the jumper fibers are enclosed within the frame assembly rather than dangling outside of the frame.

Abstract: A partition is provided for routing fiber optic communications cables into a high-density cross-connect cabinet. The partition provides improved access to the communications cables and the cable connections. The partition further permits a plurality of fiber optic communications cables entering the cross-connect cabinet at the same location to be strain-relieved at different levels of the cabinet. In a preferred embodiment, the partition includes a baseplate and a plurality of routing panels depending outwardly from the base plate at longitudinally spaced apart and laterally spaced apart locations. From the uppermost routing panel to the lower most routing panel, each routing panel is preferably located at an increased distance from the forward edge of the base plate. Each routing panel includes an arcuate portion for transitioning the fiber optic communication cables into the cross-connect cabinet.