In a first embodiment, cable sealing device is described herein for use in a port structure of fiber terminal, telecommunication enclosure, or a bulkhead. The exemplary cable sealing device comprises a unibody construction comprising a rigid body portion, the rigid portion having a generally tubular shape that includes an interior passageway extend from a first end to a second end of the rigid body portion; and an elastomeric body portion over molded onto and extending from an end of the rigid body portion, the elastomeric body portion comprises a front end having an interior sleeve that extends into interior passageway at the second end of rigid body portion and an exterior sealing sleeve that is formed over the second end of rigid body portion, and a closed end disposed opposite the open end, wherein the closed end includes a removable portion.

An optic fiber adaptor includes two flexible engaging members and two positioning walls cooperating with one another to define an insertion slot. Each engaging member has a first inclined surface and a second inclined surface disposed behind the first inclined surface. A distance between the first inclined surfaces of the engaging members decreases rearwardly so as to facilitate pushing of a casing body of a ferrule assembly into the insertion slot. A distance between the second inclined surfaces of the engaging members decreases forwardly so as to facilitate pulling of the casing body out of the insertion slot. An optic fiber connecting device having the optic fiber adaptor is also disclosed.

A multi-fiber push on (MPO) optical connector includes a housing supporting a ferrule body. The ferrule body forms an optical connection with a second MPO optical connector. The ferrule body includes a connection end having a distal end face arranged to face the second MPO optical connector when the ferrule body forms the optical connection with the second MPO optical connector. The connection end of the ferrule body defines a recess extending proximally into the ferrule body from the distal end face. A plurality of optical fibers are received in the ferrule body. Distal ends of the optical fibers are adjacent to a proximal end of the recess such that the distal ends of the optical fibers are spaced apart from the second MPO optical connector when the ferrule body forms an optical connection with the second MPO optical connector. The distal ends of the optical fibers are coated with an anti-reflective material.

There is described a fibre optic connector for insertion to a fibre optic adaptor, the fibre optic connector comprising a body portion and a latch mechanism provided on the body. The latch mechanism comprises at least one resiliently deformable latch member and the resiliently deformable latch member comprises at least one engagement element. The at least one engagement element comprises a leading surface and a trailing surface, wherein the angle between said trailing surface and said at least one resiliently deformable latch member is obtuse.

An optical fiber connection state determination system determines a state of connection between a first optical fiber configured to propagate a test light input from a light source and a second optical fiber in a connector configured to detachably connect an output side from which the test light is output in the first optical fiber and an input side of the second optical fiber to which the test light propagated by the first optical fiber and output from the first optical fiber is input, and includes: a measurement unit configured to measure an intensity of a reflected light reflected and propagating thorough the first optical fiber in the test light; and a determination unit configured to determine the state of connection between the first optical fiber and the second optical fiber in the connector based on the intensity measured by the measurement unit.

An optic fiber connector assembly, including at least one adapter and at least one connector, is provided. The adapter is correspondingly connected to the connector. The adapter includes a first housing, at least one sleeve disposed in the first housing, at least one bridging portion extending out of a side of the first housing, and at least one locking arm extending from the side and located next to the bridging portion. The sleeve extends from an inside of the first housing to the corresponding bridging portion. The connector includes a second housing, a ferrule disposed in the second housing in a penetrating manner, and a spring abutted between the second housing and the ferrule. The second housing is sleeved onto the bridging portion, the ferrule is inserted into the sleeve, and the locking arm is buckled onto the second housing.

An optical fiber array includes a plurality of single-core fibers each having a core and a cladding and each having, in a distal end surface thereof, a beam expanding portion capable of expanding a mode field diameter (MFD) of light propagating in the core, and a ferrule having an optical fiber holding hole into which the plurality of single-core fibers are inserted, and an end surface in which the optical fiber holding hole opens. A cladding diameter of each of single-core fiber in the beam expanding portion decreases toward the distal end surface. The optical fiber holding hole has a tapered portion whose inner diameter decreases toward the end surface and against which the distal end surfaces abut.

A method of manufacturing a fiber optic connector with a desired ferrule biasing force by first providing a partially assembled fiber optic connector with a front housing slideably to a rear housing. The method includes pressing on a ferrule end face at the distal portion of ferrule with a force measuring device; moving the ferrule end face a predetermined distance relative to the front end of the front housing in a direction toward the rear housing while the force measuring device is pressing on the ferrule end face; moving the rear housing in a direction toward the front end of the front housing until the force measuring device measures a predetermined force.

A windowless multi-fiber ferrule including a ferrule body. The ferrule body includes a plurality of outer slots. The ferrule body defines an inner passage that extends through a length of the ferrule body from a front end to a rear end. The inner passage includes a main chamber and a row of parallel fiber bores. The ferrule body includes a first and a second major side which each define a plurality of slots. The ferrule body includes ferrule walls which are located between the main chamber and the major sides. The ferrule walls have a first thickness at the outer slots and a second thickness at the regions between the outer slots which is thicker than the first thickness. The main chamber includes sink locations adjacent the regions between the outer slots.

A fiber management tray (10) is disclosed. The fiber management tray (10) can have a body (12) including a bottom wall (14) with side walls (16) extending outwardly from the bottom wall (14). The fiber management tray (10) can include a termination region (18) that has a first side (24) and a second side (26). The termination region (18) includes a termination panel (13) that holds connectors (20). The fiber management tray (10) can include a hinge area (56) for mounting said tray (10) to a tray tower (58) and a storage basket (32) located between the termination region (18) and the hinge area (56). The storage basket (32) can include a first pocket (44) that communicates with the second side (26) of the termination region (18) and an opposite second pocket (48) that communicates with the first side (24) of the termination region (18). The fiber management tray (10) can define at least one fiber routing path on each of the first and second pockets (44, 48) of the storage basket (32). The fiber management tray (10) can define a fiber transition opening (54) for transitioning optical fibers between the second pocket (48) of the storage basket (32) and first side (24) of the termination region (18). The fiber transition opening (54) can have an access structure for allowing optical fibers to be inserted into the fiber transition opening (54).