Abstract: Optical fiber connecting devices and methods of connecting first and second optical fibers are described. The exemplary devices have a housing composed of an upper and lower housing portions, a mechanical element disposed in a cavity of the lower housing portion, the mechanical element configured to axially align and connect the bare glass portions of the first and second optical fibers; and an actuation mechanism to open and close the splice element a plurality of times, and allows the first and second optical fibers to be positioned, secured and actuated in the mechanical element at the same or different times.

Abstract: The present invention is directed a high density optical fiber distribution system having a preterminated optical fiber termination block assemblies and an integrated splicing compartment disposed on a frame. The preterminated optical fiber termination block assembly includes optical fiber termination block with an installed multi-fiber stub cable. Each optical termination block has a plurality of termination modules has a plurality of connector adapters into which optical fiber connectors disposed on a first end of the multi-fiber stub cable are connected. A second end of the multi-fiber stub cable is connected to a distribution cable in the integrated splicing compartment, wherein the splicing compartment comprises a plurality of drawers containing optical splices and wherein each drawer of the splicing compartment can be correlated to the preterminated optical fiber termination block assembly.

Abstract: Fiber connecting devices (100) are described that include a mechanical element (160) that may be opened and closed a plurality of times using an actuation mechanism (150, 150?), where the mechanism (150, 150?) allows for securing of the glass portions (56, 56?) of two optical fibers (50, 50?) at the same or different times, and allows for connection of the optical fibers (50, 50?). Methods of connecting two optical fibers (50, 50?) using such a device (100) are also described.

Abstract: Optical fiber connecting devices and methods of connecting first and second optical fibers are described. The exemplary devices have a housing composed of an upper and lower housing portions, a mechanical element disposed in a cavity of the lower housing portion, the mechanical element configured to axially align and connect the bare glass portions of the first and second optical fibers; and an actuation mechanism to open and close the splice element a plurality of times, and allows the first and second optical fibers to be positioned, secured and actuated in the mechanical element at the same or different times.

Abstract: A cable routing system is described. More specifically, described is a cable routing system that includes a main fiber channel configured to receive a drop fiber to allow it to fit within the main fiber channel, where the channel is surrounded by a discontinuous segmented duct, and the duct comprises a continuous flange structure to provide support for the system as it is installed on or fastened to a wall or other generally flat surface.

Abstract: A cable routing system is described. More specifically, described is a cable routing system that includes a main fiber channel configured to receive a drop fiber to allow it to fit within the main fiber channel, where the channel is surrounded by a discontinuous segmented duct, and the duct comprises a continuous flange structure to provide support for the system as it is installed on or fastened to a wall or other generally flat surface.

Abstract: An inlet device is described for inserting a cable containing optical fibers into a telecommunications enclosure. The inlet device includes a housing with a strength member securing section configured to fasten at least one strength member to the housing. The inlet device further includes a fiber guide device. The inlet device may be used in a single fiber optical cable assembly or multi-fiber optical cable assembly. A method for preparing a cable assembly is also described. A telecommunications enclosure including an inlet device is also described.

Abstract: A high density optical fiber distribution system is disclosed which includes two columns of optical fiber termination blocks mounted on a standard telecommunication equipment rack. The rack includes a base and two vertical support members that define a bay. The optical fiber termination blocks are positioned on a front side of the rack and are mounted to one of the vertical support members by a mounting bracket. Each of the optical termination blocks includes a plurality of optical modules. The system can also include a vertical jumper slack storage portion adjacent to each column of optical fiber termination blocks, as well as a plurality of jumper routing troughs attached to a rear side of the rack.

Abstract: A fiber management system (100) comprises a fiber circuit platform (110) and a splice tray (150) to hold a fiber splice, the splice tray (150) being rotatably coupled to the fiber circuit platform (110). The splice tray includes at least one latching mechanism (152) rotatably engageable with the fiber circuit platform (110) and disposed on an outer portion of the splice tray. The fiber management system (100), in particular, the fiber circuit platform (110) allows a user to provide straightforward fiber circuit management at a premise or location.

Abstract: An inlet device is described for inserting a cable containing optical fibers into a telecommunications enclosure. The inlet device includes a housing and an optical device holder. The optical device holder may be configured to hold an optical fiber spice and/or an optical device such as an optical splitter, coupler or a dense wavelength division multiplexing (DWDM) device.

Abstract: An adaptor for use with a telecommunications enclosure includes a body having a port extending therethrough from a first end of the body to a second end of the body. The first end of the body is configured for mounting within an opening of a telecommunications housing along a first axis. The port adjacent the second end of the adaptor is configured to receive a connection device receptacle therein along a second axis different from the first axis. A retention device is positioned adjacent the second end of the body and configured to retain a connection device receptacle within the port.

Abstract: In one aspect, the invention described herein provides an enclosure for containing telecommunication lines and/or telecommunication line splices therein. In one embodiment, the enclosure comprises a housing wherein the housing is removeably securable to the base. The base includes an edge wall extending from the bottom plate of the base. A sealing member is disposed on an outer surface of the edge wall. The housing includes an outer side wall and an inner lip spaced apart from the outer side wall. When the housing is secured to the base, the edge wall of the base is inserted between the outer side wall and the inner lip.

Abstract: A system and method for providing a final drop in a living unit in a building. The system comprises a point-of-entry unit, such as a low profile base unit, disposed within the living unit at a location corresponding to an access position of horizontal cabling disposed in a hallway of the building that provides a first anchor point. The system also includes an adhesive-backed duct, having one or more communication lines disposed therein, mountable to a wall within the living unit. The system also includes a second anchor point, such as a wall receptacle, disposed within the living unit to receive a first communication line via the duct. The components of the system are also designed with very low impact profiles for better aesthetics within the living unit.

Abstract: A duct for distributing one or more communication lines comprises an elongated body having a length and a conduit portion with a lengthwise bore formed therein, the conduit portion containing one or more communication lines. The duct also includes a flange extending lengthwise adjacent the elongated body to mount the duct to a mounting surface. The duct also includes an adhesive layer disposed on a bottom surface of the flange. The duct may further include a strength member extending lengthwise with the flange. The strength member may be disposed between the bottom surface and the adhesive layer or within the conduit. The duct may include an open slot in the top to allow for insertion and removal of the communication line. The duct may also be configured such that the conduit portion is attached to the flange structure via a thin web of material having a thickness such that upon modest application of a peeling force, a segment of the conduit portion is detachable from the flange structure.

Abstract: A fiber management system (100) comprises a fiber circuit platform (110) and a splice tray (150) to hold a fiber splice, the splice tray (150) being rotatably coupled to the fiber circuit platform (110). The splice tray includes at least one latching mechanism (152) rotatably engageable with the fiber circuit platform (110) and disposed on an outer portion of the splice tray. The fiber management system (100), in particular, the fiber circuit platform (110) allows a user to provide straightforward fiber circuit management at a premise or location.

Abstract: In one aspect, the invention described herein provides an enclosure for containing telecommunication lines and/or telecommunication line splices therein. In one embodiment, the enclosure comprises a housing wherein the housing is removeably securable to the base. The base includes an edge wall extending from the bottom plate of the base. A sealing member is disposed on an outer surface of the edge wall. The housing includes an outer side wall and an inner lip spaced apart from the outer side wall. When the housing is secured to the base, the edge wall of the base is inserted between the outer side wall and the inner lip.

Abstract: An inlet device is described for inserting a cable containing optical fibers into a telecommunications enclosure. The inlet device includes a housing with a strength member securing section configured to fasten at least one strength member to the housing. The inlet device further includes a fiber guide device. The inlet device may be used in a single fiber optical cable assembly or multi-fiber optical cable assembly. A method for preparing a cable assembly is described. A telecommunications enclosure including an inlet device is also described.

Abstract: An enclosure includes a housing defining an internal splicing area and at least one port at least one port configured for passage of at least one telecommunications cable into the enclosure. The enclosure protects the optical fibers, optical fiber splices and optical devices contained therein. A support basket is disposed in the splicing area and extends longitudinally within the housing. The support basket is shaped to substantially conform to a portion of the circumferential shape of the splicing area. A repositionable, removable support platform is disposed on the support basket in a first orientation for storage and disposed in a second orientation for installation and maintenance of the fiber optic splices and optical devices housed in the enclosure. The optical fiber splices and optical devices are disposed in a splice tray which is adjacent to the support platform. Additionally, the support basket includes a multilayer slack storage compartment.

Abstract: An inlet device is described for inserting a cable containing optical fibers into a telecommunications enclosure. The inlet device includes a housing with a strength member securing section configured to fasten at least one strength member to the housing. The inlet device further includes a fiber guide device. The inlet device may be used in a single fiber optical cable assembly or multi-fiber optical cable assembly. A method for preparing a cable assembly is also described. A telecommunications enclosure including an inlet device is also described.

Abstract: A cable slack handling device including a base portion with a first lobe and a second lobe each joined with the base portion. The first and second lobes each have an arcuate exterior wall portion to accommodate cable slack around a perimeter of the cable slack handling device. A connection device holder is located between a portion of the first and second lobes. The connection device holder is adapted to contain cable connection devices. The connection device holder has two opposite ends each adapted to receive cables.