Abstract: Systems and methods of dispensing telecommunications cable from a network component are provided. A system includes a housing, an axle, and a spool. The housing defines an interior region and includes a cable storage portion and a mounting surface defining a receptacle. The axle is configured to removably attach to the receptacle. The spool is configured to be disposed on the axle, and has a first flange proximal to the mounting surface and a removable second flange distal to the mounting surface when the spool is disposed on the axle. The spool has a drum portion configured to support a coiled fiber optic cable and dispense the fiber optic cable as the spool rotates on the axle. Undispensed cable can be removed from the spool with the second flange removed. The cable storage portion of the housing is configured to receive the undispensed coil.

Abstract: A cable splitter module includes a housing and a connection portion at a side of the housing. The housing has a length extending along a longitudinal axis of the housing, a width extending transverse to the longitudinal axis along a width axis, and a stacking axis that is perpendicular to the longitudinal axis and to the width axis. The connection portion comprises a wall portion, a tab portion that is configured to project from the wall portion, and a slot portion that is configured to extend substantially parallel to the longitudinal axis of the housing. The connection portion is configured to connect to an adjacent receiving member that includes a slot portion that is similar to the slot portion in the connection portion and is configured to extend substantially parallel to the longitudinal axis.

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: Systems and methods of dispensing telecommunications cable from a network component are provided. A system includes a housing, an axle, and a spool. The housing defines an interior region and includes a cable storage portion and a mounting surface defining a receptacle. The axle is configured to removably attach to the receptacle. The spool is configured to be disposed on the axle, and has a first flange proximal to the mounting surface and a removable second flange distal to the mounting surface when the spool is disposed on the axle. The spool has a drum portion configured to support a coiled fiber optic cable and dispense the fiber optic cable as the spool rotates on the axle. Undispensed cable can be removed from the spool with the second flange removed. The cable storage portion of the housing is configured to receive the undispensed coil.

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: Systems and methods of dispensing telecommunications cable from a network component are provided. A system includes a housing, an axle, and a spool. The housing defines an interior region and includes a cable storage portion and a mounting surface defining a receptacle. The axle is configured to removably attach to the receptacle. The spool is configured to be disposed on the axle, and has a first flange proximal to the mounting surface and a removable second flange distal to the mounting surface when the spool is disposed on the axle. The spool has a drum portion configured to support a coiled fiber optic cable and dispense the fiber optic cable as the spool rotates on the axle. Undispensed cable can be removed from the spool with the second flange removed. The cable storage portion of the housing is configured to receive the undispensed coil.

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: Systems and methods of dispensing telecommunications cable from a network component are provided. A system includes a housing, an axle, and a spool. The housing defines an interior region and includes a cable storage portion and a mounting surface defining a receptacle. The axle is configured to removably attach to the receptacle. The spool is configured to be disposed on the axle, and has a first flange proximal to the mounting surface and a removable second flange distal to the mounting surface when the spool is disposed on the axle. The spool has a drum portion configured to support a coiled fiber optic cable and dispense the fiber optic cable as the spool rotates on the axle. Undispensed cable can be removed from the spool with the second flange removed. The cable storage portion of the housing is configured to receive the undispensed coil.

Abstract: Systems and methods of dispensing telecommunications cable from a network component are provided. A system includes a housing, an axle, and a spool. The housing defines an interior region and includes a cable storage portion and a mounting surface defining a receptacle. The axle is configured to removably attach to the receptacle. The spool is configured to be disposed on the axle, and has a first flange proximal to the mounting surface and a removable second flange distal to the mounting surface when the spool is disposed on the axle. The spool has a drum portion configured to support a coiled fiber optic cable and dispense the fiber optic cable as the spool rotates on the axle. Undispensed cable can be removed from the spool with the second flange removed. The cable storage portion of the housing is configured to receive the undispensed coil.

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: 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: Systems and methods of dispensing telecommunications cable from a network component are provided. A system includes a housing, an axle, and a spool. The housing defines an interior region and includes a cable storage portion and a mounting surface defining a receptacle. The axle is configured to removably attach to the receptacle. The spool is configured to be disposed on the axle, and has a first flange proximal to the mounting surface and a removable second flange distal to the mounting surface when the spool is disposed on the axle. The spool has a drum portion configured to support a coiled fiber optic cable and dispense the fiber optic cable as the spool rotates on the axle. Undispensed cable can be removed from the spool with the second flange removed. The cable storage portion of the housing is configured to receive the undispensed coil.

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 jack has a housing with terminals extending from opposite sides of a terminal support. Toggles coupled to the housing include passages for receiving cable wires. Closing the toggles engages the terminals and terminates wires inserted in the passages without using a special punch down tool. Viewing apertures in the toggles are connected to the wire passages and let a person see whether wires are fully inserted into the toggles for proper connection to the terminals. In some cases the toggles are pivotally coupled to the housing and adjacent the opposite sides of the terminal support, and insertion ends of the toggles face away from the jack plug opening. The jack can have a modular configuration or an integral mounting plate. A method for terminating wires includes inserting untwisted wire ends into the toggles and pivoting the toggles to intersect the wire ends with electrical terminals.

Abstract: Microduct coupling and termination devices are provided. One coupling system includes a support structure with first and second sides. Multiple couplers are configured to receive corresponding microducts on the first side. Each coupler includes a wall connected to the support structure, which defines a cavity for receiving a microduct on the support structure first side. Each coupler removably retains the microduct within the cavity and provides a seal between the wall and microduct. A port adapter has a base unit, a hinged cover, at least one cable port, and support structure with multiple couplers that receive and removably retain microducts. A microduct coupling panel has multiple couplers connected to a planar frame in a grid arrangement. A perimeter of the panel can removably couple with a corresponding coupling portion of at least one of a terminal enclosure and a port adaptor.

Abstract: Microduct coupling and termination devices are provided. One coupling system includes a support structure with first and second sides. Multiple couplers are configured to receive corresponding microducts on the first side. Each coupler includes a wall connected to the support structure, which defines a cavity for receiving a microduct on the support structure first side. Each coupler removably retains the microduct within the cavity and provides a seal between the wall and microduct. A port adapter has a base unit, a hinged cover, at least one cable port, and support structure with multiple couplers that receive and removably retain microducts. A microduct coupling panel has multiple couplers connected to a planar frame in a grid arrangement. A perimeter of the panel can removably couple with a corresponding coupling portion of at least one of a terminal enclosure and a port adaptor.

Abstract: A jack has a housing with terminals extending from opposite sides of a terminal support. Toggles coupled to the housing include passages for receiving cable wires. Closing the toggles engages the terminals and terminates wires inserted in the passages without using a special punch down tool. Viewing apertures in the toggles are connected to the wire passages and let a person see whether wires are fully inserted into the toggles for proper connection to the terminals. In some cases the toggles are pivotally coupled to the housing and adjacent the opposite sides of the terminal support, and insertion ends of the toggles face away from the jack plug opening. The jack can have a modular configuration or an integral mounting plate. A method for terminating wires includes inserting untwisted wire ends into the toggles and pivoting the toggles to intersect the wire ends with electrical terminals.

Abstract: A fiber optic cable network interface device includes a base unit defining an interior cavity. The device has a cable entrance port for a main fiber optic cable having a plurality of individual fiber optic cables and at least one cable exit port for at least one distribution fiber optic cable. The cable exit port includes a first portion of a retaining mechanism. The device includes a bulkhead connector retained to the base unit wherein the bulkhead connector is configured to connect the main cable to one of the one of the cables of the main cable to a distribution cable. The device includes a clampshell that engages the distribution fiber optic cable and transition a jacketing of the distribution fiber optic cable from an interior jacket to an exterior jacket wherein an exterior surface of the clampshell comprises a second portion of the retaining mechanism.

Abstract: A network interface device for providing a demarcation point between a central office of a telecommunications network and the customer's premise wiring, whether a copper wire cable or a fiber optic cable. The NID includes a base unit having a back wall having a perimeter and a continuous side wall extending from the perimeter of the back wall, the continuous side wall having a first wall portion and an opposing second wall portion wherein the back wall and the continuous side wall define an interior cavity. The NID includes a cable entrance port and a cable exit port in the first wall portion where both the cable entrance port and the cable exit port include a groove in an external surface. The NID includes a first connecting port and a second connecting port within the opposing second wall portion wherein the connecting ports are configured to accept the groove in the cable entrance and exit ports.

Abstract: Disclosed are exemplary embodiments of a modular plug and play connectivity platform, system and method. The disclosed modular plug and play connectivity platform provides a convergent/distribution/conversion point for multiple services and transmission mediums. In exemplary embodiments, the platform includes a base plate configured to be mounted on a wall in a premises over a junction box and to support one or more data distribution or conversion modules. An interchangeable plate is securable to the base plate and provides interfaces for the one or more data distribution or conversion modules. A cover is securable to the base plate and forms an enclosure coving any data distribution or conversion modules supported by the base plate.