A multi-fiber connector (40) that promotes physical contact with a communicating multi-fiber connector. The multi-fiber connector (40) has a connector body (44) with a front end (47) and a back end (49). The multi-fiber connector (40) also includes a ferrule (10a, 10b) with optical contacts (20a, 20b) at a front end (14a, 14b). The ferrule (10a, 10b) is spring biased toward the front end (14a, 14b) of the connector body (44). The ferrule (10a, 10b) has a pair of alignment pin openings (30a, 30b) extending into the ferrule from a front end (14a, 14b). The ferrule (10b) also has a pair of alignment pins (22) mounted within the alignment pin openings (30a, 30b). The base ends of the alignment pins (22) have a different transverse cross-sectional shape than the alignment pin openings (30a, 30b). This difference in transverse cross-sectional shapes allows the alignment pins to pivot relative to the ferrule along a major axis of the ferrule.

Embodiments of the present invention provide an optical fiber connector assembly, an optical fiber adapter, and an optical fiber connector to solve the problem of inconvenience in use caused by using a thread-locking manner in the prior art. The optical fiber connector, optical fiber adapter and optical fiber connector assembly provided in the present invention may be used as an outdoor connector to achieve plug and play. The optical fiber connector supports blind-mate, and the operation is convenient. Time taken to install and disassemble the optical fiber connector provided in the present invention is only ⅕ of the time taken to install and disassemble a common thread connector.

An optical fiber connection system for connecting a plurality optical fibers is described. The connection system comprises a first bare fiber holder comprising a first splice element and a second bare fiber holder comprising a second splice element. Each of the first and second splice elements comprises a splice body having a first end and a second end and a plurality of alternating alignment and clamping channels formed in a top surface of splice body that extend from the first end to the second end of the splice body. When the first and second bare fiber holders are mated, at least a portion of the alignment channels of the first spice element overlap a portion of the clamping channels in the second splice element and at least a portion of the clamping channels of the first splice element overlap a portion of the alignment channels of the second splice element to hold the first and second optical fibers in end to end alignment.

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 ferrule and a ferrule holder configured to hold the ferrule. The ferrule has an end face at which the optical fiber is terminated, and the ferrule holder includes a base in which the ferrule is configured to be seated. The sub-assembly includes a ferrule basket including an inner sleeve slidably coupled with an outer sleeve and configured to isolate a front end of the connector from a rear end of the connector such that the ferrule is isolated from movement of the rear end of the connector. The ferrule basket is configured to receive the ferrule holder therein.

An optoelectronic module includes a housing enclosing at least one optical transmitter or receiver and includes a release mechanism configured to engage with a cage sized and shaped to receive the housing. A cable connector for a fiber optic cable is configured to engage in a port of the module, and a slideable collar on the cable connector can keep the module engaged in the port. For example, the collar can hold tabs or arms inside the port engaged with slots or indents on a body of the connector to prevent the connector from being pulled from the port. A retainer is configured to prevent retraction of a collar on the cable connector so that the connector is not inadvertently removed from the port. By keeping the connector engaged, the retainer may by extension keep the module engaged in the cage by preventing inadvertent release of the release mechanism on the module.

The present invention discloses a type of optical fibre connector, comprising: an external shell; an internal shell, installed within said external shell; an inserted core component, contained within said internal shell and comprising an inserted core and a length of optical fibre pre-installed within said inserted core; and a spring, contained within said internal shell and located behind said inserted core, and being for exerting a pre-set axial force on said inserted core. Said internal shell includes a front part and a rear part; said rear part is assembled on said front part. Additionally, said spring is compressed between said rear part and said inserted core. In the present invention, the rear part can act as a retainer for the compressed spring and can also be for securing the Kevlar fibre extension tube of the optical cable. As a result, in comparison to the prior art, the present invention reduces the number of components of the optical fibre connector and simplifies the structure of the optical fibre connector, thus facilitating rapid on-site assembly of the optical fibre connector.

A two-piece spring push includes a main body portion and a cap. The cap is attached to the main body portion through a locking member that is disposed within a slot in the main body. The main body also includes alignment features that are received by the cap. The cap may have a bump that extends into an opening of the main body to limit the movement of optical fibers inserted therein. A front face of the cap engages a portion of a housing of a fiber optic connector when assembled.

A receptacle connector comprises a receptacle ferrule, and a receptacle housing including a cavity housing the receptacle ferrule and a cavity housing a plug connector. The receptacle ferrule includes an optical coupling surface (front surface). An opening area of the cavity on a cross section vertical to an inserting direction of the plug connector to the receptacle housing is smaller than an opening area of the cavity on the cross section vertical to the inserting direction. In a second state after being optically coupled, the optical coupling surface (front surface) is positioned inside the cavity.

A fiber optic connector is disclosed that includes a plug body having a plug end and a connector core that mounts within the plug body. The connector core includes a ferrule subassembly including a ferrule, a ferrule hub that attaches to the ferrule, a spring holder and a connector spring. The ferrule sub-assembly is assembled with the connector spring pre-compressed to an initial compressed state prior to mounting the connector core within the connector body. The plug body and the core are configured such that the connector spring is moved from the initial compressed state to a final compressed state when the connector core is loaded in the plug body. In certain examples, tuning features can be integrated into the connector core.

Embodiments disclosed herein are directed to a device and system of devices including: a connector comprising a housing comprising a groove lengthwise in a surface of the housing and a push-pull tab comprising a protrusion, a widthwise recess on the connector housing accepting protrusions on a removable anchor device that retains the connector in a port, wherein the push-pull tab releases the connector from the port using protrusions on the anchor device and the receiver device comprising one or more ports for receiving one or more connector types; and the receiver device comprising one or more ports without an anchor; said port secures a second connector type comprising a latch release mechanism; and the receiver device ports are opposite one another; wherein the opposite ports can accept a first connector and a second connector; wherein the first connector release mechanism and differs from the second connector release mechanism.