An example method of assembling an optoelectronic assembly may include aligning a receptacle with a sleeve that may have a radial flange and with a ferrule that may have a light propagation axis. The method may include axially displacing one or more of the receptacle, the sleeve, and the ferrule such that the receptacle may be positioned at least partially within the sleeve and may at least partially surround the ferrule. The method may include aligning a fiber stub that may have a fiber stub pigtail and a fiber stub flange with the receptacle. The method may include axially displacing one or both of the fiber stub and the receptacle such that the fiber stub may be positioned in close proximity with the ferrule. The method may include coupling the sleeve via the radial flange and the fiber stub via the fiber stub flange with a retention device.

The present disclosure describes an optical fiber splice closure for joining two fiber optic cables. The optical fiber splice closure comprises a strain relief assembly that securely holds the two fiber optic cables being connected, and an enclosure that houses the strain relief assembly. The configuration of the strain relief assembly allows for securing the two fiber optic cables in a compact space, thus permitting a compact enclosure of the optical fiber splice closure, while also providing quick and easy installation in the field. A method of installing fiber optic cables using the optical fiber splice closure is also disclosed. The optical fiber splice closure and ease of installation also facilitates repairing damaged fiber optic cable. A method of repairing existing fiber optic cable is disclosed.

Aspects and techniques of the present disclosure relate to an alignment device that includes a groove-type alignment structure with a support region for receiving an optical fiber inserted along a fiber insertion axis. The optical fiber has a first side and a second, opposite side. The groove-type alignment structure engages the first side of the optical fiber. The alignment device includes a stabilization structure that engages the first side of the optical fiber and a first angled transition surface that engages the second, opposite side of the optical fiber. The present disclosure also relates to an alignment system that includes a first housing piece; a second housing piece adapted to mate with the first housing piece; and a flat structure positioned between the first and second housing pieces.

An example method of assembling an optoelectronic assembly may include aligning a receptacle with a sleeve that may have a radial flange and with a ferrule that may have a light propagation axis. The method may include axially displacing one or more of the receptacle, the sleeve, and the ferrule such that the receptacle may be positioned at least partially within the sleeve and may at least partially surround the ferrule. The method may include aligning a fiber stub that may have a fiber stub pigtail and a fiber stub flange with the receptacle. The method may include axially displacing one or both of the fiber stub and the receptacle such that the fiber stub may be positioned in close proximity with the ferrule. The method may include coupling the sleeve via the radial flange and the fiber stub via the fiber stub flange with a retention device.

Aspects and techniques of the present disclosure relate to an alignment device that includes a groove-type alignment structure with a support region for receiving an optical fiber inserted along a fiber insertion axis. The optical fiber has a first side and a second, opposite side. The groove-type alignment structure engages the first side of the optical fiber. The alignment device includes a stabilization structure that engages the first side of the optical fiber and a first angled transition surface that engages the second, opposite side of the optical fiber. The present disclosure also relates to an alignment system that includes a first housing piece; a second housing piece adapted to mate with the first housing piece; and a flat structure positioned between the first and second housing pieces.

A fiber optic connector comprises a shell, an insert, and at least one terminus sub-assembly. The shell defines an interior space and has a front portion. The insert is retained in the front portion of the shell. The at least one terminus sub-assembly at least partially received and retained in the insert. The at least one terminus sub-assembly includes a ferrule, a stub optical fiber secured to the ferrule, and a holder in which the stub optical fiber terminates. At least one splice component is retained with the holder and configured to be actuated and apply a clamping force to the stub optical fiber within the holder.

A fiber optic coupling device comprises an elastomeric body. The elastomeric body includes first and second sides with a deformable alignment passage extending there between. The deformable alignment passage is configured to elastically center opposing first and second optical fibers. The deformable alignment passage includes a first portion that is configured to receive the first optical fiber having a first core. The deformable alignment passage also includes an opposing second portion that is configured to receive the second optical fiber having a second core. The first portion and the opposing second portion of the alignment passage are defined by a common encompassing periphery, and meet at a common location within the alignment passage to present the core of the received first optical fiber in coaxial alignment with the core of the received second optical fiber.

An epoxy-free, high-durability and low-cost plastic optical fiber splice design and fabrication process which meets commercial airplane environmental requirements. The splice design: (1) does not require the use of epoxy to join the end faces of two plastic optical fibers together; (2) incorporates double-crimp rings to provide highly durable pull force for the plastic optical fibers that are joined together; (3) resolves any vibration problem at the plastic optical fiber end faces using a miniature stop inside a splice alignment sleeve; and (4) incorporates a splice alignment sleeve that can be mass produced using precision molding or three-dimensional printing processes.

A pull-back fiber cable installation for multi dwelling units includes a first distribution point disposed between a first group of twelve units and a second group of twelve units, a second distribution point disposed between a third group of twelve units and a fourth group of twelve units, and a twelve fiber distribution cable optically connected to the first and second distribution points. Each fiber of the distribution cable is cut between the first and second distribution point. A first portion of the cut fiber is spliced to a first drop cable that runs to a first unit of the second group of twelve units, and a second portion of the cut fiber is spliced to a second drop cable that runs to a first unit of the third group of twelve units.

Pre-embedded optical fiber connector having an inner core, an insertion core assembly in the inner core, an outer casing, and an intermediate component and a threaded tail sleeve mounted on the inner core; a pre-embedded optical fiber is provided inside the insertion core assembly; an optical cable is inserted into an insertion channel formed by the inner core and the intermediate component; a connecting optical fiber inside the optical cable is inserted into the insertion core assembly; a press block and a push member are provided on the insertion core assembly; the push member is exposed from a first opening on the outer casing; the push member is slidable; the press block presses against and fixes the pre-embedded optical fiber and the connecting optical fiber, and a pressure of the cress block on the pre-embedded optical fiber and the connecting optical fiber varies depending on different positions of the push member.