Abstract: A pluggable electric connector is configured to be insertable into and removable from an optical communication apparatus. An optical output module outputs an optical signal and a local oscillation light. An optical reception module outputs a communication data signal generated by demodulating using the local oscillation light. A pluggable optical receptor is configured in such a manner that optical fibers are insertable thereinto and removable therefrom. A first optical fiber is connected between the optical output module and the pluggable optical receptor. A second optical fiber is connected between the optical output module and the optical reception module. A third optical fiber is connected between the optical reception module and the pluggable optical receptor. Optical fiber housing means winds extra lengths of the first to third optical fibers around a guide.

Abstract: A connector arrangement includes a plug nose body; a printed circuit board positioned within a cavity of the plug nose body; and a plug cover that mounts to the plug nose body to enclose the printed circuit board within the cavity. The printed circuit board includes a storage device configured to store information pertaining to the electrical segment of communications media. The plug cover defines a plurality of slotted openings through which the second contacts are exposed. A connector assembly includes a jack module and a media reading interface configured to receive the plug. A patch panel includes multiple jack modules and multiple media reading interfaces.

Abstract: A fiber optic telecommunications device includes a fiber optic cassette comprising a body defining a front and an opposite rear and an enclosed interior. A fiber optic signal entry location is defined on the body for a fiber optic signal to enter the interior via a fiber optic cable. An adapter block defines a plurality of fiber optic adapters and is removably mounted to the body with a snap-fit interlock, each adapter including a front outer end, a rear inner end, and internal structures allowing mating of optical connectors mounted to the front and rear ends, respectively. A removable spacer is mounted to the body, the spacer configured to expand the size of the enclosed interior of the cassette and a removable cover is mounted to the spacer. Connectorized optical fibers extend from the fiber optic signal entry location to the rear inner ends of at least some of the fiber optic adapters for relaying the fiber optic signal to fiber optic connectors to be coupled to the front outer ends of the adapters.

Abstract: A cable junction device including a housing having a bottom wall, a first forward-facing wall defining a first acute angle relative to the bottom wall, and a second forward-facing wall defining a second acute angle relative to the bottom wall. A single printed circuit board defines a third acute angle relative to the bottom wall. At least one first port extends from the first forward-facing wall toward an exterior of the housing. At least one second port extends from the second forward-facing wall toward the exterior of the housing. The at least one first port and the at least one second port each include a conductive pin configured to be directly electrically connected to the single printed circuit board.

Abstract: Examples of optical splitter systems, methods and modules enable the stacking and interconnecting of one or more optical splitter modules. One example of a splitter module has a housing and one or more connection members for connecting to adjacent instances of like splitter modules. The housing includes a plurality of cable ports providing access to an optical splitter storage area. Each connection member includes a tab and a slot, the tab configured to slidingly engage with the slot of an adjacent connection member. Sliding engagement of adjacent instances of splitter modules can form a stack of splitter modules along a stacking axis. In some cases a splitter module includes a latching mechanism to removably engage an adjacent splitter module. The latching mechanism can restrict sliding engagement and thus decoupling of the adjacent splitter modules.

Abstract: A multi-positionable tray assembly (20) for mounting within a chassis (10) of a telecommunications panel (100) is disclosed. The multi-positionable tray assembly (20) may include support arm (24) that pivotally supports a tray (22) and that allows the tray assembly (20) to be installed and removed from the chassis (10). The tray (22) and the support arm (24) cooperatively define a cable routing pathway (208) that extends through a pivot axis (A1) defined by the tray and the support arm. To minimize the required depth of the tray (10) and optimize cable routing, the tray (20) can include a cable management structure (102) with a patch panel (104) having a plurality of adapters (108) arranged along a transverse axis (A2), wherein the transverse axis is non-parallel or oblique to a front plane (A4) of the tray.

Abstract: An object is, in a pluggable optical module, to compactly house an optical fiber used for connecting optical components in a housing in which a plurality of optical components are mounted. The pluggable optical module includes: a plurality of optical components, a printed circuit board; one or more optical fibers; and optical fiber housing means. All or a part of the plurality of optical components are mounted on the printed circuit board. One or more optical fibers connect between the plurality of optical components. The optical fiber housing means includes a guide that is disposed on a plate-like member and can wind the one or more optical fibers, and mounted to be stacked with the printed circuit board on which the optical components are mounted and all or a part of optical components other than the optical components mounted on the printed circuit board.

Abstract: An extendable telecommunications patch panel (10) is disclosed. In one aspect, the patch panel can include a plurality of interconnectable connection parts (100) for holding telecommunications connectors (12), such as adapters. Each connection part (100) may be provided with features that allow the connection parts (100) to be interlocked with each other to form the extendable patch panel (10). In one aspect, a first connection feature (122) can be located on a connection part first side (102) and a second connection feature (124) can be located on a connection part second side (104). The first connection feature (122) can be configured to interlock with the second connection feature (124) of an adjacent connection part (100). The connection part (100) may also be provided with an adapter (150) that allows the connection parts (100) to be connected in a staggered formation to result in a staggered patch panel (10).

Abstract: A telecommunications cable fixation and sealing system (14) includes a telecommunications cable (18) including a jacket defining a jacket perimeter having a generally non-circular transverse cross-section and an adapter tube (26) slidably placed over the jacket of the telecommunications cable (18), the adapter tube (26) defining a tube perimeter (28) having a generally circular transverse cross-section and defining a throughhole (30) having a generally non-circular transverse cross-section that is configured to receive the telecommunications cable (18).

Abstract: A dust protector of a fiber optic connector according to the present disclosure includes a dust cap and a cleaning component. The dust cap includes a frame and a cover. The frame is configured to cover the front end of a fiber optic connector. The cover is pivotally coupled to the frame. The cleaning component is disposed on the frame to clean the fiber optic connector. The cover is configured to be closed to cover the cleaning component and to be flipped open to expose the cleaning component. The present disclosure further provides another dust protector of a fiber optic connector. In addition to being used to protect the fiber optic connector from contamination, the dust protector of the present disclosure provides additional value that avoids the need to use a separate component to clean a fiber end of a fiber optic connector.

Abstract: The present disclosure discloses a high speed optical module having a PCBA component and a passive optical element. The PCBA component includes a receiver and a transmitter. The transmitter includes an amplifier chip and a photodiode array connected to pins of the amplifier chip. The transmitter includes a laser driving chip and a base. Multiple lasers are arranged side by side in the base. The lasers are connected to the laser driving chip. A plurality of fiber interfaces are arranged on output light paths corresponding to the plurality of lasers. The passive optical element includes ferrules corresponding to the plurality of fiber interfaces, and the ferrules are correspondingly inserted into the plurality of fiber interfaces in a one-to-one relationship. The passive optical element is inserted into the PCBA component by fiber interfaces arranged on the PCBA component.

Abstract: A communications module housing includes an enclosure defining an opening, and a tray movably positioned within the enclosure. The tray includes a base, and a front rail positioned on the base, the front rail including a plurality of first mounts. The tray further includes a platform positioned on the base, the platform including a plurality of second mounts. The tray further includes a rear rail positioned on the base, the rear rail including a plurality of third mounts. The first and second mounts correspond to mounting features of the first communications modules and the third mounts correspond to mounting features of the second communications modules.

Abstract: An OVP module that connects with a hybrid trunk cable includes: a mounting frame; an overvoltage unit mounted in the mounting frame and configured to create an open electrical circuit when experiencing a voltage higher than a predetermined threshold; a first contact configured to receive a first set of power conductors from a hybrid trunk cable; a second contact configured to receive a second set of power conductors from the hybrid trunk cable; a first OVP conductor connected between the first contact and the overvoltage unit; a second OVP conductor connected between the second contact and the overvoltage unit; a third contact configured to receive a first set of power cords; a fourth contact configured to receive a second set of power cords; a third OVP conductor connected between the overvoltage unit and the third contact; and a fourth OVP conductor connected between the overvoltage unit and the fourth contact.

Abstract: High-connection density and bandwidth fiber optic apparatuses and related equipment and methods are disclosed. In certain embodiments, fiber optic apparatuses are provided and comprise a chassis defining one or more U space fiber optic equipment units. At least one of the one or more U space fiber optic equipment units may be configured to support particular fiber optic connection densities and bandwidths in a given 1-U space. The fiber optic connection densities and bandwidths may be supported by one or more fiber optic components, including but not limited to fiber optic adapters and fiber optic connectors, including but not limited to simplex, duplex, and other multi-fiber fiber optic components. The fiber optic components may also be disposed in fiber optic modules, fiber optic patch panels, or other types of fiber optic equipment.

Abstract: A fiber distribution device includes a swing frame chassis pivotally mounted to a support structure. At least a first optical splitter module is mounted to the swing frame chassis. Pigtails having connectorized ends are carried by the swing frame chassis and have portions that are routed generally vertically on the swing frame chassis. An optical termination field includes fiber optic adapters carried by the swing frame chassis. The fiber optic adapters are configured to receive the connectorized ends of the pigtails.

Abstract: A modular fiber frame is disclosed that comprises a generally rectangular frame body, a high density connection module attached to a front side of the frame body, a splitter bracket to hold a plurality of optical splitter modules on the front side of the frame body. All of the splitter connections can be made on the front side of the modular fiber frame, and a preterminated cable harness optically connected to connection ports on a back of the connection module, wherein the connection module includes a protective cover over said connection ports. In some embodiments, the exemplary modular fiber frame can utilize a second preterminated cable harness optically connected to a back of the connection module.

Abstract: A fiber optic distribution box includes a box body and detachable mounting caps to mount fiber optic connectors to the box body. The box body has a box terminal wall formed with through holes. The detachable mounting caps are disposed on the through holes and connected detachably to the box terminal wall. Each detachable mounting cap has a hollow cap body, and a mount hole formed inside the hollow cap body. The hollow cap body includes a cap bottom surface lying on the box terminal wall, and a front inclined cap surface inclined with respect to the box terminal wall. The mount hole extends through the front inclined cap surface and the cap bottom surface to communicate with a cable reception space of the box body through the respective through hole.

Abstract: A behind-the-wall optical connector an outer housing configured to be inserted into an adapter with a corresponding inner surface, a ferrule included in an annular collar to mate with a corresponding projection at an adapter opening, and a latch attached to one side of housing configured to lock the connecter into an adapter opening. The latch is further configured with a locking channel and guide to accept a pull tab with a catch at one end, the pull tab releases the connector from the adapter opening when the tab is pulled rearward or away from the adapter.

Abstract: An assembly for deploying fiber optic cable includes a housing defining a cavity and comprising a wall. The wall defines an opening allowing a fiber optic cable to pass. The assembly also includes a spool configured to store a portion of the fiber optic cable. The spool is rotatably coupled to the housing within the cavity of the housing. The assembly also includes a component module releasably coupled to the housing and comprising an adapter configured to optically couple the fiber optic cable to another fiber optic cable.

Abstract: A connector for coupling a fiber optic cable with a connection point includes a connector body at a first end of the connector and extending in a longitudinal direction and a connector housing at a second end of the connector. The connector body defines a first longitudinal conduit configured to receive a duct, and the duct is configured to slidingly receive the fiber optic cable. A compression fitting is configured to be received about a first end of the connector body and to slide relative to the connector body in the longitudinal direction to radially compress the first end of the connector body to grip the duct. The connector housing includes a second longitudinal conduit substantially aligned with the first longitudinal conduit in the longitudinal direction and a connection portion configured to couple the fiber optic cable to the connection point. The first longitudinal conduit and the second longitudinal conduit are configured to slidingly receive the fiber optic cable.

Abstract: A fiber optic transition assembly includes a drop cable including a plurality of optical fibers and an outer jacket. The assembly further includes a plurality of furcation cables, each of the plurality of furcation cables surrounding an extended portion of one of the plurality of optical fibers. The assembly further includes a plurality of biasing members, each of the plurality of biasing members surrounding a first end portion of each of the plurality of furcation cables. The assembly further includes a transition member defining an interior, wherein a second end of the outer jacket and first ends of each of the plurality of furcation cables are disposed within the interior, each of the plurality of biasing members is at least partially disposed within the interior, and the plurality of optical fibers extend from the outer jacket to the furcation cables within the interior.

Abstract: An optical fiber coating stripper includes a pair of electrodes, each of which having a discharge head portion and an electrode portion, and a gliding plasma (GP) head housing the electrodes therein. The GP head includes internal airflow channels. The pair of electrodes are disposed at a front end of the GP head and form an air gap therebetween. Each of the discharge head portion includes a curved portion with a rib-shaped protrusion extending in a longitudinal direction of the discharge head portion. In operation, the electrodes are connected to non-alternating electrically positive and negative polarities. When a gas flows through the internal airflow channels in a direction a back end of the GP head toward the front end, a tongue-shaped GP flow is formed in the air gap between the rib-shaped protrusions of the discharge head portions.

Abstract: An apparatus includes a sensor and a processor. The sensor may be configured to generate a first video signal. The processor may be configured to search for a flickering effect in a frame of the first video signal, determine a location and a region of pixels to modify within the frame in response to the flickering effect, determine a modification based on the flickering effect, perform the modification of the region of pixels by determining average values of pixels based on the location of the region of pixels over consecutive frames of the first video signal and generate a second video signal in response to the modification of the region of pixels and the first video signal. The second video signal may present a modified version of the region of pixels to mask the flickering effect when viewing the second video signal on a display.

Abstract: An optical circuit switch includes a fiber hole array, a plurality of internal optical fibers, a collimating lens array, a MEMS mirror array, and a reflective surface. The fiber hole array includes an array of receptacles shaped to accept respective internal optical fibers. The collimating lens array is positioned adjacent to the fiber hole array. Each collimator of the collimating lens array optically couples light into or out of a corresponding one of the internal optical fibers. The fiber hole array, the collimator, the MEMS mirror array and the reflective surface are positioned relative to one another such that light exiting each of the internal optical fibers passes through its corresponding collimator and is redirected by a first mirror within the MEMS array towards the reflective surface, which directs the light back towards a second mirror of the MEMS mirror array, which in turn redirects the light towards a second internal optical fiber.

Abstract: An adapter panel arrangement including a chassis and a panel of adapters. The adapters defining open rearward cable connections and open forward cable connections of the panel arrangement. The adapters being arranged in arrays that slide independently of other adapter arrays to provide access to the open rearward and open forward cable connections.

Abstract: Aspects of the present disclosure relate to a cable bend radius guide. The cable bend radius guide comprises a flexibly rigid linear material of a predetermined length having a plurality of pairs of corresponding bend radius markers each separated by a predetermined distance along the predetermined length. The cable bend radius guide further comprises at least one constraint configured to fasten a first bend radius marker and a second bend radius marker of each pair of bend radius markers together to cause a portion of the flexibly rigid linear material between the first bend radius maker and second bend radius marker of each pair of bend radius markers to generate a substantially circular loop having a minimum bend radius corresponding to a cable's minimum bend radius.

Abstract: Fiber mounting units for supporting an optical fiber for fiber laser systems are disclosed and include a base body having a fiber end attachment section, a fiber guide section, and a connection section arranged between the fiber end attachment section and the fiber guide section. The fiber end attachment section is adapted to attach a receiving element, which holds a fiber end portion of the optical fiber, the fiber guide section is adapted to guide a fiber central portion of the optical fiber, and the connection section is configured as a flexure bearing between the fiber end attachment section and the fiber guide section.

Abstract: In embodiments, methods and systems for implementing fiber optic cable network testing using a fiber optic cable network testing platform are provided. A fiber optic cable network testing adapter assembly comprises an attachment and a port. The attachment attaches the adapter assembly to a mobile device and the port receives a fiber optic cable. A fiber optic cable network testing application receives, via a camera of the mobile device, light data from the cable. The fiber optic cable is coupled to the port to transmit the light data to the application. The application is part of the fiber optic cable network testing platform, the platform provides integrated fiber optic cable network testing. The application analyzes the light data based on a fiber optic cable network testing option to generate testing results data. The application communicates the testing results data using an interface to facilitate presenting the testing results data.

Abstract: A rack-level breakout box, system, and method for distributing high-fiber count optical fiber cables to one or more network racks. External routing of incoming and outgoing cables around the rack is kept neat and orderly, with one large cable serving a fully populated rack and, optionally, multiple racks. A flexible mounting configuration is further provided.

Abstract: A method of installing a fiber optic cable (10) upon an overhead power line structure, the overhead power line structure including an overhead power line support (60) and an overhead power line (90) carried by the overhead power line support (60), the method comprising the steps of passing an end of the fiber optic cable (10) through a bore formed in an insulator (120); positioning the insulator (120) at an installation location adjacent to the overhead power line support (60) with the fiber optic cable (10) located within the bore in the insulator (120); bonding the insulator (120) in place once positioned in the said installation location; connecting the insulator (120) to a first end of a conductive carrier (160); and connecting a second end of the conductive carrier (160) to the overhead power line (90) such that the fiber optic cable (10) is supported by the conductive carrier (160) and the insulator (120) as it passes from a first side of the overhead power line support (60) to a second side thereof.

Abstract: A fiber optic splice enclosure includes a basket. The basket includes an outer shell, the outer shell including an outer sidewall defining at least a portion of a periphery of the basket. The basket further includes an insert disposed within the outer shell, the insert including a first sidewall and a second sidewall spaced apart from each other along a transverse axis and each extending along a longitudinal axis to define an inner channel therebetween. The first sidewall and the second sidewall are each further spaced apart from the outer sidewall along the longitudinal axis to define a first outer channel and a second outer channel. The fiber optic splice enclosure further includes a splice tray assembly including at least one splice tray, the splice tray assembly disposed within the inner channel.

Abstract: A cable breakout assembly includes: a cable including a plurality of signal-carrying members enclosed in a protective jacket; a plurality of connector modules, each of the connector modules having at least one side wall and a connector mounted thereto, wherein the connector modules are arranged in serial relationship along an axis, with a gap between adjacent connector modules; and at least one flex member extending between the connector modules that substantially prevents the axial spacing of the gaps between adjacent connector modules from increasing, but enables adjacent connector modules to flex about the axis relative to each other. Each of the signal carrying-members is connected with a respective connector.

Abstract: An optical connecting system for connecting a first and a second optical device includes a first and a second multi-fiber device connector included in the first and second optical device and a multi-fiber optical connection cable including a plurality of optical fibers and having a first and a second multi-fiber cable connector at a first and second end thereof and being adapted to be connected to the first and second multi-fiber device connector. The optical devices are configured to transmit to and/or receive from the other optical device wanted optical data signals via optical fibers of the multi-optical fiber connection cable.

Abstract: A swing arm assembly for a utility vault housing a utility equipment includes a swing arm bracket for supporting the utility equipment and a latch support arm both rotatably coupled to a sidewall of the utility vault. A latch pin is attached to one of the swing arm bracket and the latch support arm and a locking slot is formed in the other one of the swing arm bracket and the latch support arm for slidably receiving the latch pin. The locking slot has a first locking end that locks the latch pin in a stowed position for stowing the utility equipment and a second locking end that locks the latch pin in a service position for servicing the utility equipment.

Abstract: A telecommunications chassis comprises a cable sealing portion defining at least one cable opening configured to sealably receive a cable and a module mounting portion extending from the cable sealing portion, which further comprises a housing defining an open front closable by a door to define an interior, a rear wall, a right wall, and a left wall. A plurality of module mounting locations is provided in a vertically stacked arrangement, each configured to receive a telecommunications module through the open front. An exterior of the housing includes a first column of radius limiters defining curved profiles for guiding cables from the front toward the rear with bend control. A second column of radius limiters in the form of spools is spaced apart and generally parallel to the first column of radius limiters and a third column of radius limiters, at least some of which are in the form of spools, is also spaced apart and generally parallel to the first and second columns of radius limiters.

Abstract: A plug assembly comprising at least one elongate ferrule terminating an one optic fiber and arranged in parallel to an actuating axis, a plug housing the ferrule and such that an end of the ferrule is exposed at a forward end thereof, the forward end configured for insertion into a receptacle, an elongate release lever for releasably securing the plug housing to the receptacle, the lever comprising a first end fixed to the plug housing towards the forward end and a flexible free end, and an actuating assembly cooperating with the flexible free end and rotatable about the actuating axis between a position where the flexible free end is positioned spaced from the housing and a position where the flexible free end is positioned immediately adjacent the housing.

Abstract: An optical connector having at least one removable integrated assembly tool for terminating an optical fiber cable is described. The connector comprises a housing configured to mate with a receptacle, a collar body disposed in the housing, a backbone that retains the collar body in the housing, a removable funnel-shaped and a fiber boot. The collar body secures a ferrule secured at a first end thereof, and includes mechanical element disposed in an intermediate portion and a buffer clamping portion near a second end of the collar body. The backbone has a mounting structure surrounding a central bore at one end. The funnel-shaped fiber guide attaches to the mounting structure to facilitate insertion of an optical fiber into the connector, and wherein the fiber boot is attachable to the mounting structure after the fiber guide has been removed.

Abstract: Fiber optic enclosures, terminal assemblies, end cap assemblies, and methods of sealing fiber optic enclosures are disclosed. The terminal assembly of a fiber optic enclosure may include an input fiber sealing assembly and an output fiber sealing assembly. The input fiber sealing assembly may include an input fiber insert positioned in an input fiber channel of the cap body, an input fiber compression plate positioned in the input fiber channel, and an input fiber compression member for compressing the insert between the fiber compression plate and the base plate. The output fiber sealing assembly may include an output fiber insert positioned in the output fiber channel of the cap body, an output fiber compression plate positioned in the output fiber channel, and an output fiber compression member for compressing the insert between the fiber compression plate and the base plate.

Abstract: An optical fiber rack includes a rack part on which a plurality of termination units are located, a first optical fiber housing part in which extra length wiring parts of a plurality of first optical fibers are housed, a second optical fiber housing part in which an extra length wiring part of a second optical fiber connected with any of the plurality of termination units is housed, a partition plate partitioning the first optical fiber housing part from the second optical fiber housing part, and, a plurality of optical fiber guides attached to the partition plate and arranged in the vertical direction. The optical fiber guide comprises a first guide part housing the first optical fibers toward to the first optical fiber housing part, and a second guide part housing the second optical fiber passing through an opening provided in the partition plate.

Abstract: A fiber optic communications arrangement includes a closure with an interior volume; the closure including at least one cable through-port in communication with the interior volume; and an expansion component attached to an exterior portion of the closure and having an interior region in communication with the closure interior volume. The expansion component includes ruggedized fiber optic adapters mounted thereto. Each of the ruggedized fiber optic adapters includes at least one connector port for receiving ruggedized fiber optic connectors.

Abstract: Advantageous optical fiber harnessing members for connector assemblies and related methods of use are provided. The present disclosure provides improved harnessing members configured to provide bend control of optical fibers in connector assemblies, and related methods of use. More particularly, the present disclosure provides advantageous systems/methods for the design and use of internal harnessing members configured to provide bend control of optical fibers in duplex or quad uniboot connector assemblies. Disclosed herein are advantageous harnessing members providing bend control of optical fibers in connector assemblies (e.g., duplex or quad uniboot connector assemblies), thereby allowing optical fiber cable (e.g., light-construction cable, such as coated fiber with a 250 ?m diameter) to be successfully and reliably deployed in such connector assemblies.

Abstract: A telecommunications module defines an interior with separate right and left chambers. An optical component is housed within the left chamber. Signal input and output locations are exposed to the right chamber. The right chamber allows excess fiber to accumulate without bending in a radius smaller than a minimum bend radius. A dual-layered cable management structure is positioned within the right chamber that defines a lower cable-wrapping level and a separate upper cable-wrapping level. The upper cable-wrapping level is defined by a removable cable retainer mounted on a spool defining the lower-cable wrapping level. Cabling carrying the input and output signals are passed between the right and left chambers before and after being processed by the optical component.

Abstract: An optical connector retaining unit includes: an optical connector retaining member that retains an optical connector of a distal end of an optical fiber in a connection standby state being optically connected to nothing; and a reflecting section that reflects visible light emitted from the distal end of the optical fiber after led into a proximal end of the optical fiber opposite to the distal end thereof provided with the optical connector, at an inclination angle of 45 degrees or less with respect to an optical axis of the emitted visible light, or a scattering section that scatters visible light emitted from the distal end of the optical fiber such that scattered light includes light within the inclination angle of 45 degrees or less with respect to the optical axis of the emitted visible light.

Abstract: A modular fiber optic patch panel system is disclosed. The system includes an enclosure and at least one patch panel module mounted in the enclosure. The enclosure includes a chassis with multiple module bays, each configured to receive a corresponding patch panel module. The patch panel modules each include a module housing, an input connector and an output connector. An optical directional coupler is connected to the input connector and a photodiode is positioned adjacent the optical directional coupler to measure an optical power level conveyed on the optical fiber. A data acquisition device is connected to the photodiode to capture the optical power level data and a microcontroller is connected to the data acquisition device to store the data.

Abstract: An optical fiber connection system includes a first and a second optical fiber, each with end portions that are terminated by a first and a second fiber optic connector, respectively. A fiber optic adapter connects the first and the second fiber optic connectors. A fiber alignment apparatus includes V-blocks and gel blocks. Each of the fiber optic connectors includes a connector housing and a sheath. The end portions of the optical fibers are positioned beyond distal ends of the respective connector housings. The sheath is slidably connected to the connector housing and slides between an extended configuration and a retracted configuration. The sheath covers the end portion of the respective optical fiber when the sheath is at the extended configuration and exposes the end portion when at the retracted configuration. The end portions of the optical fibers are cleaned when slid between the V-blocks and the gel blocks.

Abstract: A secondary disconnect assembly for use with a circuit breaker moveable between a connected position and a disconnected position includes a first secondary disconnect apparatus and a second secondary disconnect apparatus. The first secondary disconnect apparatus includes a first coupling portion having at least one high speed communications connector. The second secondary disconnect apparatus includes a second coupling portion removably coupled to the first coupling portion. The second coupling portion includes at least one opening configured to receive the high speed communications connector when the circuit breaker is moved from the disconnected position to the connected position to enable high speed data transmission through the first coupling portion and the second coupling portion.

Abstract: A fiber panel system includes a chassis and at least blades configured to mount to the chassis. Each blade is moveable relative to the chassis between a retracted (closed) position and at least one extended position. Cable slack is managed at the front and/or rear of each chassis to facilitate movement of the blades without pulling or bending the cables beyond a maximum bend limit. Each blade may be locked into one or more positions relative to the chassis.

Abstract: A communications connection system includes an adapter module defining at least first and second ports and at least one media reading interface mounted at one of the ports. The first adapter module is configured to receive a fiber optic connector at each port. Some type of connectors may be formed as duplex connector arrangements. Some types of adapters may include ports without media reading interfaces. Some types of media reading interfaces include contact members having three contact sections.

Abstract: The present disclosure relates to a telecommunications distribution hub having a cabinet that defines a primary compartment. The cabinet also includes one or more main doors for accessing the primary compartment. Telecommunications equipment is mounted within the primary compartment. The distribution hub further includes a secondary compartment that can be accessed from an exterior of the cabinet without accessing the primary compartment. A grounding interface is accessible from within the secondary compartment.

Abstract: A fiber optic connector storage apparatus for storing a fiber optic connector having an exposed ferrule includes a housing and a dust cap portion. The housing defines a socket to receive and hold the fiber optic connector. The dust cap portion is integral with the housing and is configured to receive and protect the exposed ferrule when the fiber optic connector is inserted into the socket.