A connector storage includes a storage block including a plurality of chambers. Each of the plurality of chambers includes an open first end at a front wall and a substantially closed second end at a rear wall. The storage block is configured to include first voids and/or second voids between adjacent ones of the plurality of chambers. Each of the plurality of chambers includes a substantially circular perimeter wall that includes first and second wall portions between the respective chamber and respective ones of the first and second voids. The perimeter wall is configured to have a first diameter that is smaller than a second diameter of a circle that circumscribes corners of the fiber optic connector. The first and second wall portions are configured to deform into respective ones of the first and second voids to receive and securely grip the corners of the fiber optic connector while minimizing a contact area between the perimeter wall and the connector so as to reduce a force required to insert the connector into the storage block and remove the connector from the storage block.

A dustcap comprises a body having a cylindrical portion configured to receive a ferrule of an optical fiber connector, and an end portion opposite the cylindrical portion. The end portion includes a receptacle. The dustcap has a built-in cleaner disposed within the receptacle. The dustcap further comprises a removable cover configured to couple to the end portion of the dustcap. In another embodiment, the end portion includes a flat surface, the cleaner is disposed on the flat surface of the end portion, and the cover is configured to receive the end portion of the dustcap. In another embodiment, the cover has a receptacle and the cleaner is disposed within the receptacle, whereas the body comprises an end portion configured to receive at least a portion of the cover with the built-in cleaner. Embodiments encompass cleaner assemblies and adapter dustcaps having built-in cleaners.

A small form factor dust cap for a fiber-optic connector includes a main body having a front portion, a middle portion, a rear portion, and an internal opening extending within the main body from the rear portion toward the front portion, the main body formed by two long side walls joined by a short top wall and an oppositely placed short bottom wall, a pair of cutouts in each of the respective two long side walls and located nearer to one of the short top wall and the short bottom wall, an extension extending rearwardly from the middle portion and having a free end, and an engagement mechanism at the free end of the extension to engage a housing of the fiber optic connector. The dust cap is also combined with a small form factor fiber optic connector.

A dust-proof apparatus for a fiber optic connector has a base; a ferrule receiving sleeve positioned on a mating end of the base; two primary cantilevered arms extending substantially in parallel from the mating end of the base, with the ferrule receiving sleeve being positioned therebetween; and a secondary cantilevered arm extending from the mating end of the base, and having a locking projection receiving hole disposed on a free end.

Optical fiber connections and their applications in downhole assemblies are described herein. The downhole assembly includes a well completion element with an end that couples with a corresponding well completion element. An optical fiber extends along at least a portion of the well completion element and transmits an optical signal using a first mode. The well completion element includes an optical fiber connector that is coupled to the optical fiber. The connector also includes a mode converter that receives the optical signal from the optical fiber and converts the optical signal from the first mode to a second larger mode. This second larger mode may be more robustly communicated to a corresponding optical fiber connector affixed to the corresponding well completion element.

The present disclosure relates to fiber management systems and methods for facilitating assembling fiber optic devices in an efficient manner by allowing pre-processed and tested optical fibers to be pre-routed on a substrate prior to installation in their corresponding fiber optic devices.

Fiber optic connectors comprising multiple footprints along with cable assemblies and methods for making the same are disclosed. In one embodiment, the optical connector comprises a housing and a ferrule. The housing comprises a longitudinal passageway between a rear end and a front end. The fiber optic connector may be converted from a first footprint to a second footprint by a conversion housing that fits about a portion of the housing. The optical connectors disclosed may be tunable for improving optical performance and may also include a spring for biasing the ferrule to a forward position as desired.

The present disclosure provides an optical fiber connector, comprising an integrated ferrule assembly and an integrated outer housing assembly, the ferrule assembly being adapted to be fitted into the housing assembly. The ferrule assembly at least comprises an inner housing, a spring, a multi-hole ferrule, a multi-fiber optical cable, a sleeve and a thermal shrinkable tube. The housing assembly at least comprises an outer housing, an outer tail tube and an outer protection cap. In the present disclosure, a plurality of components such as the inner housing, the spring, the multi-hole ferrule, multi-fiber optical cable, the sleeve, the thermal shrinkable tube and the like can be preassembled into an integrated ferrule assembly, and a plurality of components such as the outer housing, the outer tail tube, the outer protection cap and the like can be preassembled into an integrated outer housing assembly; then, a worker only needs to insert the integrated ferrule assembly into the integrated outer housing assembly on site, thereby completing assembling operation of the whole optical fiber connector conveniently and quickly.

Devices having at least one connector port associated with a rotating securing features are disclosed. A device for making optical connections comprising a shell, at least one connection port, and at least one rotating securing feature is disclosed. In one embodiment, the at least one connection port is disposed on a device with at the least one connection port comprising an optical connector opening extending from an outer surface of the device into a cavity of the device and defining a connection port passageway. The at least one rotating securing feature is associated with the connection port passageway, and the at least one rotating securing feature is secured to the device along a rotational axis that is not aligned with a longitudinal axis of the at least one connection port.

The invention is a connector structure for connecting optical conduits comprising a first connector part (11) and a second connector part (21) connectible to each other, the first connector part (11) comprises a head unit comprising a head portion (18) arranged with a conical receiving space part (35), a connector housing element (22), and a first resilient element (26) in an inner space of the connector housing element (22), and a first conduit channel adapted for arranging a first optical conduit is formed in the first connector part (11), and the second connector part (21) comprises a second head portion (16) having a spherical end portion adapted for being circularly seated on the conical side wall (30) of the conical receiving space part (35) of the first head portion (18) of the first connector part (11) in case the first connector part (11) is connected to the second connector part (21), and a second conduit channel adapted for arranging a second optical conduit is formed in the second connector part (21). The invention is, furthermore, a crimping device for securing an optical conduit into a connector part, a push-out device for removing an optical conduit from a connector part, and a light blocking element for a connector part.