Devices, systems and methods to prevent damage to power and communication conductors located in cold occurring regions, with an elongated cylindrical tubular assembly of closed cell foam within a braided/woven layer that can be sealed to provide longitudinal strength and a snag resistant durable and flexible outer coating. The assembly along with communication and power lines is pulled through new power and communication ducts and conduits and in retrofitting existing power and communication ducts, so that the assembly reduces the volume spacing in the ducts/conduits that can be damaged by water intrusion which expands during freeze conditions.

A fibre optic pulling grip assembly, comprising a sleeve, connection sleeve, swivel pulling eye unit, fitting, clamp, and a securing unit is provided. The sleeve has a sleeve coupling portion and sleeve body. The connection sleeve has a connection sleeve head and connection sleeve body. The swivel pulling eye unit has a pulling eye swivel portion and pulling eye body. The connection sleeve body is configured for fixed assembly of the pulling eye body therewithin, the sleeve coupling portion is configured for fixed assembly of the connection sleeve body therewithin, and the fitting is configured for fixed assembly of the sleeve coupling portion therewithin. The clamp has a clamp securing portion and clamping portion. The securing unit moves longitudinally toward the clamping portion, such that the fitting is moved to assemble to the sleeve coupling portion, applying pressure to the sleeve coupling portion supported by the connection sleeve body.

Devices, systems and methods to prevent damage to power and communication conductors located in cold occurring regions, with an elongated cylindrical tubular assembly of closed cell foam within a braided/woven layer that can be sealed to provide longitudinal strength and a snag resistant durable and flexible outer coating. The assembly along with communication and power lines is pulled through new power and communication ducts and conduits and in retrofitting existing power and communication ducts, so that the assembly reduces the volume spacing in the ducts/conduits that can be damaged by water intrusion which expands during freeze conditions.

A wire-anchoring system for use with a core about which a wire is desired to be wound utilizes a lanyard assembly which includes a cord portion and a connector body connected to the cord portion. The elongated connector body has two opposite ends and a hollow interior including an opening which opens out of the body at one end thereof and into which the terminal end of the wire can be inserted for purposes of anchoring the wire to the connector body. In addition, the cord portion of the wire has a free end which is securable to the outer surface of the core adjacent the securement location thereon so that by securing the free end of the cord portion to the outer surface of the core and anchoring the terminal end of the wire to the connector body, the wire is anchored to the core for an operation involving the winding of the wire about the core.

A system and method for improving the efficiency and effectiveness of installing and pulling microducts through subterranean pathways is provided. The system includes a device that is placed over at least one microduct and secured through tapered screws that enter through the end cap of the body of the device and into at least one microduct. The tapered screw both expands the microduct, pressing it against the inner wall of the body and guide rod, as well as securing the microduct to the cap end of the body. Securing the microducts against seal provides further protection from water, debris, and other contaminants, and the expansion of the microducts provides friction and adherence to the body, aiding in keeping microducts in place. The device further includes a pulling apparatus connected to the device body, allowing it to be connected to a pulling mechanism for installation of the microducts.

A optical fiber connecting device includes a hollow main body and a dust-proof unit. The hollow main body includes a first hollow inserting portion for insertion of a fiber optic connector, a second hollow inserting portion oppositely of the first hollow inserting portion, and a flange between the first and second hollow inserting portions. The second hollow inserting portion has a threaded outer surface. The dust-proof unit includes a dust-proof sleeve that has a threaded inner surface. The dust-proof sleeve is removably sleeved around the second hollow inserting portion by an inter-engagement of the threaded inner and outer surfaces.

An optical fiber connector sub-assembly for an optical fiber connector includes a ferrule configured to hold an optical fiber therein along an axis of the connector, a ferrule basket configured to hold the ferrule at a front portion of the connector, a retaining member having a front end portion configured to hold the ferrule holder and a rear end portion configured to receive a fiber optic cable, and a boot configured to be coupled with retaining member. The ferrule basket includes a base portion and a stem portion that extend rearward from the base portion. An outer periphery of the base portion includes two flat portions arranged at a right angle relative to one another, and first ends of the two flat portions that are nearest to one another along the outer periphery of the base portion are connected to one another by a curved bottom portion. Two side curved portions extend from second ends of the two flat portions that are furthest from one another along the outer periphery of the base portion, and top curved portion connects the two side curved portions.

A protective caddy for the installation of an optical fiber cable in optical fiber ducting which temporarily protects a duplex optical fiber cable assembly for an optical fiber duplex connector during insertion of the assembly into a length of ducting. The duplex optical fiber cable assembly comprises a duplex optical fiber cable and a pair of optical fiber connector sub-assemblies. The protective caddy comprises a pair of receptacles, each for receiving one of the optical fiber connector sub-assemblies. Each receptacle has a recess for protectively receiving the termination end of one of the optical fiber ferrules. In use, both the duplex optical fiber cable and the pair of optical fiber connector sub-assemblies are held to the elongate body so that the termination ends are protected by the recesses during insertion of the protective caddy and duplex optical fiber cable assembly into the length of ducting.

A ferrule assembly comprises a ferrule mounted in an opening of a ferrule back body. The ferrule assembly is mounted at an end of an optical fibre extending through the ferrule along an axial direction. The ferrule assembly is passed through a tubular section and then through a biasing member. The back body is then inserted into an opening of a back body holder and attached to the back body holder. The back body holder prevents the ferrule assembly from passing back through the biasing member. The insertion comprises moving the ferrule assembly relative to the back body holder in the axial direction. During the relative movement, an orientation of the back body relative to the back body holder, determined by a guide element of the back body, is maintained. The tubular section may for example be a duct as narrow as 3 mm.

A optical fiber connecting device includes a hollow main body and a dust-proof unit. The hollow main body includes a first hollow inserting portion for insertion of a fiber optic connector, a second hollow inserting portion oppositely of the first hollow inserting portion, and a flange between the first and second hollow inserting portions. The second hollow inserting portion has a threaded outer surface. The dust-proof unit includes a dust-proof sleeve that has a threaded inner surface. The dust-proof sleeve is removably sleeved around the second hollow inserting portion by an inter-engagement of the threaded inner and outer surfaces.