A method of splicing an optical fiber of the invention splices a first optical fiber cable and an optical fiber in a splicing box, the first optical fiber cable is a drop cable or an indoor cable, the optical fiber is drawn from a second optical fiber cable, the method splices a terminal of the first optical fiber cable and the optical fiber. The method includes: sliding a unit base holding an extended-optical-fiber-attached splice along a rail in a direction in which the unit base approaches a grasper; thereby inserting an inserted optical fiber grasped by the grasper between halved elements of a mechanical splice; and splicing the inserted optical fiber and an extended optical fiber by butt-jointing an end of the inserted optical fiber to the extended optical fiber.

Disclosed is fiber optic splice protection device, comprising: a closure including a cover and a chassis; wherein a circle of groove is formed on mating edge of four walls of one of the cover and the chassis, and an elastic sealing member is placed in the groove; a circle of projection is formed on mating edge of four walls of another of the cover and the chassis; the cover is locked on the chassis in the way of locking, when the cover is locked on the chassis, the projection is pressed against the elastic sealing member and is embedded into the groove in order to achieve the seal locking between the cover and the chassis. The cover of this application may ease to open repeatedly, and the good seal performance between the cover and the chassis can be achieved.

An optical connector comprises a first optical waveguide including a plurality of cores each extending along a first direction, the first optical waveguide having a first end face, wherein the cores are arranged on the first end face at positions except a position of a central axis of the first optical waveguide, and a first lens having a second end face and a third end face in the first direction, the first lens having an optical axis extending along the first direction. The first optical waveguide and the first lens are arranged so that the central axis of the first optical waveguide coincides with the optical axis of the first lens. The second end face is positioned facing the first end face, and the third end face extends along a plane perpendicular to an optical axis of the first optical waveguide.

A method for manufacturing a fiber optic connector assembly, comprising: providing a ferrule having a first fiber and a cable having a second fiber; adjusting the ferrule to locate the first fiber at a first predetermined orientation, and adjusting the cable to locate the second fiber at a second predetermined orientation; and inserting the first fiber located at the first predetermined orientation and the second fiber located at the second predetermined orientation into a alignment tool received in a housing of a fiber optic connector. Wherein the first and second predetermined orientations are set so that a distance between a center of a fiber core of the first fiber and a center of a fiber core of the second fiber is equal to an absolute value of a difference between a distance from a center of a coat layer to the center of the fiber core of the first fiber and a distance from a center of a coat layer to the center of the fiber core of the second fiber when the first fiber located at the first predetermined orientation and the second fiber located at the second predetermined orientation are inserted into the alignment tool.

A processing system to connectorize optical cables includes processing stations on a table arrangement; and a track arrangement. The processing stations include: a strip-clean-cleave station that creates prepared ends of cable fibers and stub fibers; a splice station that fusion splices the prepared ends of cable and stub fibers; an overmold station that injection molds hubs around the splices; a UV cure station and a heat cure station for the injection molding; and a connector assembly station at which an optical connector is assembled at an end of each optical cable.

An optical fiber splicing structure of the invention includes: an optical fiber connector that is capable of holding an optical fiber at both sides thereof in a radial direction; a receiving optical fiber that is provided inside the optical fiber connector and has a hole opening at an end face of a connection end thereof; a solid refractive index matching layer that is formed at the end face of a connection end of the receiving optical fiber and enters the hole; and an external optical fiber that is to be butt-jointed to the receiving optical fiber by being butt-jointed to the receiving optical fiber at the end faces thereof with the refractive index matching layer interposed therebetween.

The invention relates to a new device for aligning two expanded beam optical fibers, including an alignment tube in which a relay lens is mounted. The invention is particularly intended to the integration into connectors, notably current connectors.

Disclosed is fiber optic splice protection device, comprising: a closure including a cover and a chassis; wherein a circle of groove is formed on mating edge of four walls of one of the cover and the chassis, and an elastic sealing member is placed in the groove; a circle of projection is formed on mating edge of four walls of another of the cover and the chassis; the cover is locked on the chassis in the way of locking, when the cover is locked on the chassis, the projection is pressed against the resilient seal and is embedded into the groove in order to achieve the seal locking between the cover and the chassis. The cover of this application may ease to open repeatedly, and the good seal performance between the cover and the chassis can be achieved.

A method of splicing an optical fiber of the invention splices a first optical fiber cable and an optical fiber in a splicing box, the first optical fiber cable is a drop cable or an indoor cable, the optical fiber is drawn from a second optical fiber cable, the method splices a terminal of the first optical fiber cable and the optical fiber. The method includes: sliding a unit base holding an extended-optical-fiber-attached splice along a rail in a direction in which the unit base approaches a grasper; thereby inserting an inserted optical fiber grasped by the grasper between halved elements of a mechanical splice; and splicing the inserted optical fiber and an extended optical fiber by butt-jointing an end of the inserted optical fiber to the extended optical fiber.

A fiber optic splicing assembly is disclosed having an assembly housing and a fiber storing device. The assembly housing has a mounting side and an opposite outer facing side. The fiber storing device is removably mounted to the assembly housing, and is at least partially received in an assembly receiving passageway of a mounting wall.