A very small form factor multifiber fiber optic connection system includes an adapter and mating connectors with complementary prealignment features for prealigning multifiber ferrules in the adapter to prevent guide pin stubbing. The adapter has a prealignment feature formed on at least one interior side of each individual connector port and the connectors have a complementary prealignment formation along a side wall of the connector housing assembly. Each prealignment feature slidably engages the prealignment formation of a fiber optic connector as the fiber optic connector is inserted into the individual connector port to prealign a multifiber ferrule of the fiber optic connector in the adapter.
The present disclosure relates to a fiber optic adapter mating multiple fiber optic connectors to establish optical transmission. The fiber optic adapter includes an adapter housing defining an outer appearance of the fiber optic adapter and having a top wall, bottom wall and side walls therebetween, having a first end and an opposite second end along a length direction, a space formed within the adapter housing between the first end and the second end; and multiple partition walls extending between the first end and the second end to divide the space into multiple channels. Each channel is provided with a first elongated arms adjacent to the first end and extending toward the second end, and the first elongated arm is configured to be formed integrally with the top or bottom wall of the adapter housing.
An optical fiber connector, an optical fiber adapter and an optical fiber connection system. The optical fiber connector (110) is configured to be mated with the optical fiber adapter (160). The optical fiber connector (110) includes an inner housing (111), a ferrule assembly (121), a rear body (122), an elastic member (133), and a sealing component (134). The sealing component (134) is clamped between the inner housing (111) and the rear body (122). The optical fiber adapter is configured to receive the optical fiber coupler. The optical fiber connection system includes the above-mentioned optical fiber connector and the optical fiber adapter.
A fiber optic network system comprises a trunk-to-node cabling assembly for connecting a trunk cable to at least 16 network nodes. The trunk-to-node cabling assembly consists of a trunk VSFF uniboot connector for terminating the trunk cable, a plurality of VSFF adapters and a plurality of cable assemblies terminated by VSFF connectors. The trunk-to-node cabling assembly is configured to connect the trunk cable to the at least 16 network nodes without any prefabricated shuffle component or mid span breakout component between the trunk cable and the at least 16 network nodes.
A behind-the-wall optical connector having an outer housing configured to be inserted into an adapter with a corresponding inner surface, and a latch is attached to at least one side of housing configured to lock the connector into an adapter opening. A backbody, an integrated backbody or an external clip retains the ferrule assembly with a ferrule, biased forward toward a proximal end of the connector housing.
A multi-fiber, fiber optic connector may include a reversible keying arrangement for determining the orientation for plugging the connector into an adapter to thereby allow for a change in polarity of the connection to be made on site. The connector housing may be configured to engage with a removable key that may be engaged with the housing in at least two different locations to provide the plug-in orientation, or the housing may have slidably displaceable keys movable between multiple positions on the housing.
A fiber optic adapter includes an adapter housing defining a connector port for mating with a fiber optic connector in either of two connector polarity orientations. A polarity cap is releasably securable to the adapter housing in either of two adapter polarity orientations, each of which only permits insertion of the connector in one respective connector polarity orientation. The changing polarity of the adapter is facilitated by removing the polarity cap from the adapter housing, inverting the polarity cap, and reinstalling the inverted polarity cap.
An optical connector holding two or more LC-type optical ferrules is provided. The optical connector includes an outer body, an inner front body accommodating the two or more LC-type optical ferrules, ferrule springs for urging the optical ferrules towards a mating connection, and a back body for supporting the ferrule springs. A removable inner front body for polarity change is disclosed. A multi-purpose rotatable boot assembly for polarity change is disclosed. The multi-purpose boot assembly can be pushed and pulled to insert and remove the micro connector from an adapter receptacle.
An optical signal device for connecting to a receptacle of an optical motherboard includes an optical module and an optical connector coupled to the optical module. The optical connector attaches to the receptacle of the optical motherboard to optically connect the optical module to the optical motherboard. The optical connector has a first optical interface axis and a second optical interface axis different from the first optical interface axis. The optical connector is configured to convey optical signals to and/or from the optical motherboard along at least one of the first or second optical interface axes.
The present invention relates to the pluggable connection of an optoelectronic module with an optoelectronic connector assembly from a location exterior to the optoelectronic connector assembly. An optoelectronic module comprises a housing having a proximate end and a rear end in a longitudinal direction; a ferrule arranged adjacent to the proximate end of the housing; an electrical contact arranged adjacent to the proximate end of the housing and stacked with the ferrule in a vertical direction; a biasing members configured to bias the ferrule in the longitudinal direction once pressed; and a guiding member extending in the longitudinal direction and configured to guide the optoelectronic module connected to another optoelectronic module. The optoelectronic connection between the optoelectronic module and the optoelectronic connector assembly has blind mating features.
A multi-fiber, fiber optic connector is interchangeable between a male connector and a female connector by including a pin retainer having a releasable retention device configured to lock the pins in place within the retainer. The retention device may be opened, for example, with a release tool, to free the retention pins for removal of the pins. A method for switching a connector between a male connector configuration and a female connector configuration may be possible as a result of the releasable retention configuration.
The fiber optic adapter according to the present disclosure may include a housing comprising a top wall, a bottom wall, two opposing sidewalls, and a partition wall dividing the housing into two channels. A central shutter pair is attached to the partition wall and has a first arm and second arm configured to extend into the two channels respectively. The first and second arms are sized and shaped to cooperatively close at least one channel, and at least one of the first arm or second arm is configured to be resiliently movable in a direction to open the channel upon insertion of a fiber optic connector. The fiber optic adapter may prevent the entry of dust and other debris.
A fiber optic connection assembly includes a cage and an adapter assembly releasably securable in the cage. The adapter assembly includes an insert cartridge and an adapter in the insert cartridge. The adapter maters with fiber optic connectors. The insert cartridge has at least one actuator for selectively releasing the adapter assembly from the cage. The adapter assembly is bi-directionally loadable into and extractable from the cage. The fiber optic connection assembly is usable to install a fiber optic trunk cable by plugging a trunk cable connector into the adapter before inserting the adapter assembly into the cage. The adapter assembly can also be extracted from the cage while one or more connectors remain mated with the adapter.
An MPO connector has an elongated outer housing and a push-pull boot. The front end portion of the push-pull received in the interior of the extended rear portion of the outer housing. The front end portion of the push-pull boot is linked to the opposing side portions of the outer housing such that the outer housing moves backward in relation to the main body when the push-pull boot is pulled backward. The front end portion of the push-pull boot can comprise opposing side walls with opposing side tabs projecting outward for operably connecting the push-pull boot to the elongated outer housing of the MPO connector.
A passive optical alignment coupling between two bodies each having a complementary interstitial two-dimensional planar array of protrusions defining an array of interstices. Each array of protrusions defines an array of discrete protrusions separated and isolated from one another on the surface of the corresponding bodies. When the bodies are pressed together, the array of protrusions defined on one body intermesh with protrusions defined on the other body with protrusions of one body received in corresponding interstices defined on the other body. The protrusion surfaces of each adjacent pair of protrusions are in point contact. The first body is removably attachable to the second body to define a demountable coupling, with the first array of alignment features against the second array of alignment features to define an elastic averaging coupling, thereby passively aligning the first body to the second body.
An MPO connector has an elongated outer housing and a push-pull boot. The front end portion of the push-pull received in the interior of the extended rear portion of the outer housing. The front end portion of the push-pull boot is linked to the opposing side portions of the outer housing such that the outer housing moves backward in relation to the main body when the push-pull boot is pulled backward. The front end portion of the push-pull boot can comprise opposing side walls with opposing side tabs projecting outward for operably connecting the push-pull boot to the elongated outer housing of the MPO connector.
A fiber optic connection assembly includes a cage and an adapter assembly releasably securable in the cage. The adapter assembly includes an insert cartridge and an adapter in the insert cartridge. The adapter maters with fiber optic connectors. The insert cartridge has at least one actuator for selectively releasing the adapter assembly from the cage. The adapter assembly is bi-directionally loadable into and extractable from the cage. The fiber optic connection assembly is usable to install a fiber optic trunk cable by plugging a trunk cable connector into the adapter before inserting the adapter assembly into the cage. The adapter assembly can also be extracted from the cage while one or more connectors remain mated with the adapter.
A passive optical alignment coupling between two bodies each having a complementary interstitial two-dimensional planar array of protrusions defining an array of interstices. Each array of protrusions defines an array of discrete protrusions separated and isolated from one another on the surface of the corresponding bodies. When the bodies are pressed together, the array of protrusions defined on one body intermesh with protrusions defined on the other body with protrusions of one body received in corresponding interstices defined on the other body. The protrusion surfaces of each adjacent pair of protrusions are in point contact. The first body is removably attachable to the second body to define a demountable coupling, with the first array of alignment features against the second array of alignment features to define an elastic averaging coupling, thereby passively aligning the first body to the second body.
In one aspect the present disclosure provides a latching connector. The latching connector comprises a housing that is configured to engage with a mating connector along a coupling axis. The housing includes a lever connected to the housing. The lever is configured to selectively disengage the latching connector from the mating connector. The housing further includes an extending member connected to the lever.
H01R 13/633 - Additional means for facilitating engagement or disengagement of coupling parts, e.g. aligning or guiding means, levers, gas pressure for disengagement only
H01R 43/26 - Apparatus or processes specially adapted for manufacturing, assembling, maintaining, or repairing of line connectors or current collectors or for joining electric conductors for engaging or disengaging the two parts of a coupling device
H01R 24/64 - Sliding engagements with one side only, e.g. modular jack coupling devices for high frequency, e.g. RJ 45
An optical connector module having a plurality of discrete optical benches (B) inputting/outputting optical signals, each including: a base (b) defining an array of reflective surfaces (MM) and supporting an array of optical fibers (F) defining optical channels with inputs/outputs in optical alignment with corresponding reflective surfaces (MM), thereby forming optical inputs/outputs of the corresponding optical bench. A carrier (CB) commonly supports the optical benches (B), with the optical benches (B) fixedly mount thereon in a desired spatial arrangement with the optical inputs/outputs of the optical benches matching optical inputs/outputs of the external optical component. The carrier (CB) is structured to physically connect to the external component. The carrier includes passive alignment features (PA) for demountable coupling to the external component, wherein the carrier (CB) is at least one of directly mounted to the top of the external component, or detachably mounted to the external component via a receptacle or foundation positioned relative to the inputs/outputs of the external component.
An optical connector module having a plurality of discrete optical benches inputting/outputting optical signals, each including: a base defining an array of reflective surfaces and supporting an array of optical fiber array defining optical channels with inputs/outputs in optical alignment with corresponding reflective surfaces, thereby forming optical inputs/outputs of the corresponding optical bench. A carrier commonly supports the optical benches, with the optical benches fixedly mount thereon in a desired spatial arrangement with the optical inputs/outputs of the optical benches matching optical inputs/outputs of the external optical component. The carrier is structured to physically connect to the external component. The carrier includes passive alignment features for demountable coupling to the external component, wherein the carrier is at least one of directly mounted to the top of the external component, or detachably mounted to the external component via a receptacle or foundation positioned relative to the inputs/outputs of the external component.
A new fiber optic connector provides a very small form factor with reduced size. The fiber optic connector may comprise a single-body housing having a front end and rear end in a longitudinal direction, two ferrules accommodated in the housing and protruding from the front end of the housing, a back housing positioned adjacent to the rear end of the housing, two springs positioned between the two ferrules and the back housing to urge the two ferrules to move forward, and a boot assembly connected to the rear end of the housing. The housing comprises a latch arm extending obliquely upwards, and the latch arm is in a depressed state when the fiber optic connector is mating with an adapter.
Cross-compatible VSFF connection systems include optical connectors that are compatible with at least two types of adapters and adapters that are compatible with at least two types of optical connectors. Optical connectors have one or both of connector latch recesses and depressible latches, and likewise adapters have one or both of adapter latch arms and adapter latch recesses. Dual latch function connectors and adapters are capable of connection to a mating components that have only one type of latch structure, e.g., only recesses or only latches. Connection systems can be duplex or MT and may facilitate push-pull boot remote release and polarity change.
An optical connector has a connector housing assembly for holding one or more ferrules, the connector housing assembly having a height align a vertical alignment axis and a width perpendicular to the height. The connector housing assembly includes an inner front body and an outer release component, the outer release component being movable in relation to the inner front body between a front position and a back position. The optical fiber connector is configured to mate with a receptacle having an upper receptacle hook such that the upper receptacle hook is received in the upper receptacle hook recess and latches with the upper hook retainer surface when the outer release component is in the front position and such that the upper ramp lifts the upper receptacle hook out of the upper receptacle hook recess when the outer release component moves to the back position.
Cross-compatible VSFF connection systems include optical connectors that are compatible with at least two types of adapters and adapters that are compatible with at least two types of optical connectors. Optical connectors have one or both of connector latch recesses and depressible latches, and likewise adapters have one or both of adapter latch arms and adapter latch recesses. Dual latch function connectors and adapters are capable of connection to a mating components that have only one type of latch structure, e.g., only recesses or only latches. Connection systems can be duplex or MT and may facilitate push-pull boot remote release and polarity change.
An optical connector holding two or more LC-type optical ferrules is provided. The optical connector includes an outer body, an inner front body accommodating the two or more LC-type optical ferrules, ferrule springs for urging the optical ferrules towards a mating receptacle, and a back body for supporting the ferrule springs. The outer body and the inner front body are configured such that four LC-type optical ferrules are accommodated in a small form-factor pluggable (SFP) transceiver footprint or eight LC-type optical ferrules are accommodated in a quad small form-factor pluggable (QSFP) transceiver footprint. A mating receptacle (transceiver or adapter) includes internal alignment slots configured to accept a corresponding alignment key on connector outer housing to ensure alignment and orientation for maximum signal transfer between opposing ferrule end faces.
A method of polishing an optical fiber connector comprises providing a unitary connector housing defining an interior containing a first ferrule and a second ferrule, each ferrule having an angle-polished end face and being located in an original rotational position, the unitary connector housing comprising a perimeter wall extending 360° about the interior, first and second ferrule springs biasing the first and second ferrules forward in the interior of the unitary housing, the unitary connector housing having a contiguous two-ferrule opening through a front end of the unitary connector housing, each of the first and second ferrules extending through the contiguous two-ferrule opening such that the first and second ferrules protrude forwardly from the front end of the unitary connector housing; and using a tool to rotate the first ferrule in the housing about a longitudinal axis while the second ferrule remains in the original rotational position.
B24B 41/06 - Work supports, e.g. adjustable steadies
B24B 13/00 - Machines or devices designed for grinding or polishing optical surfaces on lenses or surfaces of similar shape on other workAccessories therefor
G02B 6/38 - Mechanical coupling means having fibre to fibre mating means
31.
DEMOUNTABLE CONNECTION OF AN OPTICAL CONNECTOR USING A FOUNDATION HAVING FEATURES FOR INTEGRATED OPTICAL COUPLING AND DEMOUNTABLE MECHANICAL COUPLING
A demountable connection of an optical connector using a foundation having features for integrated optical coupling and demountable coupling. The foundation provides for demountable passive alignment connection to an optical connector. The foundation is permanently attached and aligned to a PIC chip. The foundation includes optical elements that redirect and reshape incident light to follow a desired light beam shape and path between the optical connector and the optoelectronic device. The foundation may include a combination of different optical elements having optical properties that produces the desired light beam quality and direction. The foundation also includes passive alignment features that matches the passive alignment features on the facing side of the optical connector. The foundation has a unitary, monolithic body that is provided with the optical elements and the passive alignment features.
A demountable connection of an optical connector using a foundation having features for integrated optical coupling and demountable coupling. The foundation provides for demountable passive alignment connection to an optical connector. The foundation is permanently attached and aligned to a PIC chip. The foundation includes optical elements that redirect and reshape incident light to follow a desired light beam shape and path between the optical connector and the optoelectronic device. The foundation may include a combination of different optical elements having optical properties that produces the desired light beam quality and direction. The foundation also includes passive alignment features that matches the passive alignment features on the facing side of the optical connector. The foundation has a unitary, monolithic body that is provided with the optical elements and the passive alignment features.
An LBM package and method for packaging an LBM using a stamped metallic mirror array that folds light beams, correct beam shapes, fold and/or redirect beam propagations. The mirror array can be integrated or assembled inside an LBM to provide beam shaping and redirection of the high-power beams near the laser diode. The LBM incorporates a stamped metallic freeform mirror or reflector with an off-axis parabolic shape is configured to fold and collimate laser beam. A precision stamping process is deployed to produce an array of miniature, freeform mirrors in high volume applications. The mirror array simplifies the optical path and eliminates passive components such as refractive lenses and dichroic filters that combine RGB beams. Stamped metallic optical components with micro-scale freeform mirrors in the LBM are tolerant of high temperatures and can thermally diffuse heat away from the reflective surface for high power applications.
A reversible polarity fiber optic connector includes an outer housing having a front end, a rear end, and a receiving space defined between the front end and rear end; a ferrule assembly accommodated within the receiving space and configured to form an optical connection with a receptacle, the ferrule assembly including at least one ferrule protruding from the front end of the outer housing and configured to switch between a first position and second position; and a boot assembly rotatable connected to the rear end of the outer housing. When the boot assembly is rotated to an unlock position, the boot assembly is able to disconnect with the outer housing and the ferrule assembly is able to switch between the first position and second position.
An LBM package and method for packaging an LBM using a stamped metallic mirror array that folds light beams, correct beam shapes, fold and/or redirect beam propagations. The mirror array can be integrated or assembled inside an LBM to provide beam shaping and redirection of the high-power beams near the laser diode. The LBM incorporates a stamped metallic freeform mirror or reflector with an off-axis parabolic shape is configured to fold and collimate laser beam. A precision stamping process is deployed to produce an array of miniature, freeform mirrors in high volume applications. The mirror array simplifies the optical path and eliminates passive components such as refractive lenses and dichroic filters that combine RGB beams. Stamped metallic optical components with micro-scale freeform mirrors in the LBM are tolerant of high temperatures and can thermally diffuse heat away from the reflective surface for high power applications.
Various embodiments disclosed herein are directed to an optical fiber connector. The optical fiber connector comprises at least one ferrule, at least one ferrule spring, a connector housing for holding at least one ferrule and at least one ferrule spring such that at least one ferrule spring is loaded to urge the at least one ferrule forward. The connector housing comprises an upper wall portion, the upper wall portion comprising a recess running lengthwise. The optical fiber connector further comprises a remote release comprising a front portion slidably received in the recess, and the remote release is configured to be pulled backward in relation to the connector housing whereby the front portion slides in the recess for releasing the optical fiber connector from a mating adapter.
In a fiber optic connection system, an adapter has an expandable wall portion that snaps onto a connector and latches with a latch knob of the connector housing. A lock and an extractor are disposed on the connector housing. During insertion, the extractor is in a forward position as the connector housing is inserted into the adapter. The adapter moves the lock backward relative to the housing and extractor, toward an unlocking position, until the adapter snaps onto the latch knob. Then the lock returns to the locking position to lock the connector to the adapter. To extracts the connector, the extractor is pulled backward. This moves the lock backward to unlock the connector from the adapter. Further pulling unlatches the adapter from the latch knob by expanding the expandable wall portion and extracts the connector.
In a fiber optic connection system, an adapter has an expandable wall portion that snaps onto a connector and latches with a latch knob of the connector housing. A lock and an extractor are disposed on the connector housing. During insertion, the extractor is in a forward position as the connector housing is inserted into the adapter. The adapter moves the lock backward relative to the housing and extractor, toward an unlocking position, until the adapter snaps onto the latch knob. Then the lock returns to the locking position to lock the connector to the adapter. To extracts the connector, the extractor is pulled backward. This moves the lock backward to unlock the connector from the adapter. Further pulling unlatches the adapter from the latch knob by expanding the expandable wall portion and extracts the connector.
A multi-fiber, fiber optic connector is interchangeable between a male connector and a female connector by including a pin retainer having a releasable retention device configured to lock the pins in place within the retainer. The retention device may be opened, for example, with a release tool, to free the retention pins for removal of the pins. A method for switching a connector between a male connector configuration and a female connector configuration may be possible as a result of the releasable retention configuration.
An optical connector holding two or more LC-type optical ferrules is provided. The optical connector includes an outer body, an inner front body accommodating the two or more LC-type optical ferrules, ferrule springs for urging the optical ferrules towards a mating connection, and a back body for supporting the ferrule springs. A removable inner front body for polarity change is disclosed. A multi-purpose rotatable boot assembly for polarity change is disclosed. The multi-purpose boot assembly can be pushed and pulled to insert and remove the micro connector from an adapter receptacle.
A multi-fiber, fiber optic connector may include a reversible keying arrangement for determining the orientation for plugging the connector into an adapter to thereby allow for a change in polarity of the connection to be made on site. The connector housing may be configured to engage with a removable key that may be engaged with the housing in at least two different locations to provide the plug-in orientation, or the housing may have slidably displaceable keys movable between multiple positions on the housing.
An optical fiber connector, an optical fiber adapter and an optical fiber connection system. The optical fiber connector (110) is configured to be connected to the optical fiber adapter (160) in an abutting manner. The optical fiber connector (110) comprises an inner housing (111), a ferrule assembly (121), a rear main body (122), an elastic member (133) and a sealing portion (134), wherein the inner housing (111) comprises a front end portion (112), a rear end portion (113) and an open space (115), the open space (115) extending from the front end portion (112) to the rear end portion (113), the front end portion (112) being configured to allow insertion of the optical fiber adapter (160), and the rear end portion (113) being provided with a first clamping portion (116); the ferrule assembly (121) is arranged in the open space (115) of the inner housing (111), and the ferrule assembly (121) is configured to accommodate an optical fiber and is at least partially exposed from the front end portion (112); the rear main body (122) is connected to the rear end portion (113) of the inner housing (111), and the rear main body (122) has a first fitting portion (129), the first fitting portion (129) being configured to fit with the first clamping portion (116) in a clamping manner; the elastic member (133) is arranged in the open space (115) and is clamped between the ferrule assembly (121) and the rear main body (122); and the sealing portion (134) is clamped between the inner housing (111) and the rear main body (122). The optical fiber adapter is configured to receive the optical fiber coupler. The optical fiber connection system comprises the optical fiber connector and the optical fiber adapter.
The fiber optic adapter may include a main body having a first end portion and a second end portion spaced apart along a length direction, the first end portion having at least a first port configured for receiving at least one ferrule, the second end portion having at least a second port configured for receiving a fiber optic connector; and a sleeve holder provided within the main body and between the first end portion and second end portion such that the first port is in communication with the second port to establish an optical connection. The first port has holding elements to define a receiving space to receive the ferrule, and the receiving space is configured to be expanded when inserting the at least one ferrule into the first port. The fiber optic adapter may receive a ferrule without the need of an outer housing or a spring.
A fiber optic adapter assembly reduced in size from a SFP footprint to a SC footprint to accommodate a first fiber optic connector on a first side within one or more ports, and a second fiber optic connector on a second side within one or more ports. The first fiber optic connector is a duplex fiber optic connector with an overall length of about 50 mm and the second fiber optic connector is a behind-the-wall connector with an overall length of about 15 mm thereby reducing the overall length of a connector and adapter assembly for increasing optical fiber density.
An optical fiber connector can terminate a plurality of optical fiber cables, each with a jacket encasing at least one optical fiber and a strength element. A connector housing has a back post. The optical fibers of the plurality of optical fiber cables extend into the connector housing through the back post. A single crimp ring crimps the strength members of the plurality of optical fiber cables onto the back post. In a method of terminating a plurality of optical fiber cables, the cables are inserted through a single crimp ring, optical fibers of each of the cables are terminated in a multifiber ferrule, the cables are loaded into a back body of a connector housing, and strength members of the cables are crimped onto a back post using a single crimp ring.
An optical fiber connector with a housing configured to hold a plurality of optical fiber ferrules is selectively reconfigurable between a first configuration and a second configuration different from the first configuration. The housing can have different widths in the first and second configurations. The ferrules can have different ferrule arrangements in the first and second configurations. The optical fiber connector can be mateable with different types of receptacles in the first and second configurations. Reconfiguration can be achieved by disconnecting a rear housing from a plurality of front housings at first set of attachment points, rotating the rear housing 180° in relation to the front housings, and attaching the rear housing to the front housings at the second set of attachment points.
G02B 6/08 - Light guidesStructural details of arrangements comprising light guides and other optical elements, e.g. couplings formed by bundles of fibres the relative position of the fibres being the same at both ends, e.g. for transporting images with fibre bundle in form of plate
G02B 6/40 - Mechanical coupling means having fibre bundle mating means
An optical fiber connector with a housing configured to hold a plurality of optical fiber ferrules is selectively reconfigurable between a first configuration and a second configuration different from the first configuration. The housing can have different widths in the first and second configurations. The ferrules can have different ferrule arrangements in the first and second configurations. The optical fiber connector can be mateable with different types of receptacles in the first and second configurations. Reconfiguration can be achieved by disconnecting a rear housing from a plurality of front housings at first set of attachment points, rotating the rear housing 180° in relation to the front housings, and attaching the rear housing to the front housings at the second set of attachment points.
In a fiber optic connector, a ferrule body is received in a connector housing. A displaceable guide pin is movable in relation to the ferrule body. A spring yieldably biases the displaceable guide pin forward along a longitudinal axis of the fiber optic connector. The displaceable guide pin is displaced backward along the longitudinal axis in relation to the ferrule body and resiliently compresses the spring as the fiber optic connector is connected to another fiber optic component. In a multifiber ferrule assembly, a ferrule base is connected to a ferrule body. A displaceable guide pin is movably connected to the ferrule body for movement in relation to the ferrule body along a longitudinal axis between an extended position and a retracted position. A spring between the displaceable guide pin and the ferrule base yieldably biases the displaceable guide pin to the extended position.
An optical fiber array module that can accommodate variations in diameters of the optical fibers in the fiber array within anticipated tolerance, to accurately and securely retain the optical fibers in grooves in the module without using any solder interface or epoxy interface between the optical fibers and the supporting components. The fiber array module of the present invention relies on elasto-plastic interfaces for mechanical deformation, as opposed to solder reflow or epoxy curing, to accommodate variations in diameters of the optical fibers in the fiber array as supported in grooves between a substrate and a cover.
A fiber optic connector terminates a drop cable. A connector housing can include a back post where the drop cable to enters the housing. A cable clamp insert is least partially received in the back post. The cable clamp insert defines a passage for receiving the drop cable. A crimp ring is crimped onto the back post to secure the cable clamp insert to the housing and clamp the cable clamp insert onto the drop cable. Fiber optic connectors can also have a cable clamp insert and a cable clamp retainer that couples to the rear end portion of the housing whereby the cable clamp retainer pushes the cable clamp insert forward in the housing and applies an increasing force to create a tight connection between the housing and the cable clamp insert.
A fiber optic connector terminates a drop cable. A connector housing can include a back post where the drop cable to enters the housing. A cable clamp insert is least partially received in the back post. The cable clamp insert defines a passage for receiving the drop cable. A crimp ring is crimped onto the back post to secure the cable clamp insert to the housing and clamp the cable clamp insert onto the drop cable. Fiber optic connectors can also have a cable clamp insert and a cable clamp retainer that couples to the rear end portion of the housing whereby the cable clamp retainer pushes the cable clamp insert forward in the housing and applies an increasing force to create a tight connection between the housing and the cable clamp insert.
An optical connector holding one or more optical ferrule assembly is provided. The optical connector includes an outer body, an inner front body accommodating the one or more optical ferrule assembly, ferrule springs for urging the optical ferrules towards a mating receptacle, and a back body for supporting the ferrule springs. The outer body and the inner front body are configured such that four optical ferrule assembly are accommodated in a small form-factor pluggable (SFP) transceiver footprint or eight optical ferrule assembly are accommodated in a quad small form-factor pluggable (QSFP) transceiver footprint. A receptacle can hold one or more connector inner bodies forming a single boot for all the optical fibers of the inner bodies.
Fiber optic network systems are implemented, at least in part, using very small form factor (VSFF) interconnect components such as VSFF duplex connector; VSFF mechanical transfer ferrule (MT) connector; VSFF duplex uniboot connector; VSFF MT uniboot connector; VSFF duplex adapter; VSFF MT adapter; VSFF duplex pluggable transceiver; VSFF MT pluggable transceiver; VSFF patch cable assembly; VSFF trunk cable; and/or VSFF breakout cable. The VSFF fiber optic network systems can define fiber breakout cabling that connects large trunk cables to many peripheral network locations. The network systems can define branches and sub-branches from a trunk cable. The network systems can define cross-connect sub-networks between sets of transceivers or adapters. The network systems can define a trunk-to-transceiver cabling assembly for connecting a trunk cable to at least 32 transceiver ports.
G02B 6/44 - Mechanical structures for providing tensile strength and external protection for fibres, e.g. optical transmission cables
G02B 6/38 - Mechanical coupling means having fibre to fibre mating means
H04B 10/00 - Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
Fiber optic network systems are implemented, at least in part, using very small form factor (VSFF) interconnect components such as VSFF duplex connector; VSFF mechanical transfer ferrule (MT) connector; VSFF duplex uniboot connector; VSFF MT uniboot connector; VSFF duplex adapter; VSFF MT adapter; VSFF duplex pluggable transceiver; VSFF MT pluggable transceiver; VSFF patch cable assembly; VSFF trunk cable; and/or VSFF breakout cable. The VSFF fiber optic network systems can define fiber breakout cabling that connects large trunk cables to many peripheral network locations. The network systems can define branches and sub-branches from a trunk cable. The network systems can define cross-connect sub-networks between sets of transceivers or adapters. The network systems can define a trunk-to-transceiver cabling assembly for connecting a trunk cable to at least 32 transceiver ports.
H04B 10/00 - Transmission systems employing electromagnetic waves other than radio-waves, e.g. infrared, visible or ultraviolet light, or employing corpuscular radiation, e.g. quantum communication
G02B 6/38 - Mechanical coupling means having fibre to fibre mating means
G02B 6/40 - Mechanical coupling means having fibre bundle mating means
G02B 6/42 - Coupling light guides with opto-electronic elements
A passive optical alignment coupling between an optical connector having a first two-dimensional planar array of alignment features and a foundation having a second two-dimensional planar array of alignment features. One of the arrays is a network of orthogonally intersecting longitudinal grooves defining an array of discrete protrusions that are each in a generally pyramidal shape with a truncated top separated from one another by the orthogonally intersecting longitudinal grooves, and the other array is a network of longitudinal cylindrical protrusions. The cylindrical protrusions are received in the grooves, with protrusion surfaces of the cylindrical protrusions in contact with groove surfaces and the top of the discrete protrusions contacting the surface bound by the cylindrical protrusions. The optical connector is removably attachable to the foundation to define a demountable coupling, with the first array of alignment features against the second array of alignment features to define an elastic averaging coupling.
Devices and methods for connecting optical fibers are provided. In some embodiments, connectors and adaptors for two-fiber mechanical transfer type ferrules are disclosed. In some embodiments, MT connectors, such as simplex, duplex, and quad micro-MT adaptors are disclosed. In some embodiments, MT adaptors, such as simplex, duplex, and quad adaptors are disclosed. In some embodiments, optical fiber cables that modularly coupled with at least one optical fiber connector, adaptor, and other optical fiber cable the cable is configured to provide a remote release from an adaptor receptacle.
A multifiber ferrule has a generally forward-facing angled ferrule contact surface that is skewed with respect to the widthwise axis of the ferrule such that the angled ferrule contact surface defines a widthwise skew angle with respect to the widthwise axis. A multifiber optical connector has a connector housing assembly that holds at least one of this type of ferrule. The connector housing assembly can hold two such ferrules so that the ferrule contact surfaces are angled in opposite widthwise directions and so that a broad side of the first ferrule opposes a broad side of the second ferrule in parallel, spaced apart relationship therewith. A polarity-changeable multifiber optical connector is also provided that includes a multifiber ferrule with a generally forward-facing ferrule contact surface at an oblique angle to the longitudinal axis.
A field installable fiber optic connector for use with polymer optical fibers includes a housing that releasably connects to another optical device. A mechanical termination assembly is located in the housing to mechanically terminate a plurality of individual fibers of the polymer optical fibers. Ferrules are supported by the housing. Each ferrule is positioned to receive one of the individual fibers from the mechanical termination assembly.
A connection system may include fiber optic connectors and an optical receptacle into which the connectors are plugged. The fiber optic connectors are constructed so that the width of the connectors is small. Eight fiber optic connectors can be received in an opening of a QSFP style transceiver.
Connectors for a multiport assembly are disclosed. The multiport assembly can include a multi- port device that communicatively couples multiple sets or pairs of connectors, such as optical connectors, together. The connectors include a housing, securing features to inhibit unintentional withdrawal of the connectors from the multi-port device and a seal positioned for engaging the multi-port device in the port upon reception of the connector in the port.
Connectors for a multiport assembly are disclosed. The multiport assembly can include a multiport device that communicatively couples multiple sets or pairs of connectors, such as optical connectors, together. The connectors include securing features to inhibit unintentional withdrawal of the connectors from the multiport device.
In a connector for terminating a cable, a connector housing has a rear end portion including a first shoulder. An inner connector assembly is received in the connector housing. The inner connector assembly includes at least one ferrule exposed and a back body with a back post. At least one strength member is secured to the back post. A rear bracing member is received in the connector housing. The rear bracing member has a front end portion and a rear end portion spaced apart along the longitudinal axis. The front end portion of the rear bracing member is configured to engage the back body and the rear end portion of the rear bracing member is configured to engage the first shoulder of the connector housing such that the rear bracing member substantially braces the back body against rearward displacement along the longitudinal axis relative to the connector housing.
A connection system for a printed circuit board employs either an inline or transverse board-mounted connector for holding board-mounted optical fibers. A plug-in connector can blind mate with the board-mounted connector. The plug-in connector has a plug-in connector body, a plug-in ferrule, and a plug-in ferrule holder. The plug-in holder latches with the plug-in connector body at either of two positions to selectively configure the plug-in connector for blind mating with either the inline or transverse board-mounted connector. The board-mounted fibers can be supported by a board-mounted ferrule assembly including a ferrule and a ferrule holder that is configured to selectively attach the board-mounted ferrule assembly to either of an inline board-mounted connector body and a transverse board-mounted connector body.
H01R 13/631 - Additional means for facilitating engagement or disengagement of coupling parts, e.g. aligning or guiding means, levers, gas pressure for engagement only
H01R 12/71 - Coupling devices for rigid printing circuits or like structures
H01R 24/60 - Contacts spaced along planar side wall transverse to longitudinal axis of engagement
H05K 1/18 - Printed circuits structurally associated with non-printed electric components
67.
OPTICAL FIBER CONNECTOR WITH IMPROVED CABLE RETENTION STRENGTH
In a connector for terminating a cable, a connector housing has a rear end portion including a first shoulder. An inner connector assembly is received in the connector housing. The inner connector assembly includes at least one ferrule exposed and a back body with a back post. At least one strength member is secured to the back post. A rear bracing member is received in the connector housing. The rear bracing member has a front end portion and a rear end portion spaced apart along the longitudinal axis. The front end portion of the rear bracing member is configured to engage the back body and the rear end portion of the rear bracing member is configured to engage the first shoulder of the connector housing such that the rear bracing member substantially braces the back body against rearward displacement along the longitudinal axis relative to the connector housing.
G02B 6/38 - Mechanical coupling means having fibre to fibre mating means
H01R 13/514 - BasesCases formed as a modular block or assembly, i.e. composed of co-operating parts provided with contact members or holding contact members between them
H01R 13/56 - Means for preventing chafing or fracture of flexible leads at outlet from coupling part
H01R 11/28 - End pieces consisting of a ferrule or sleeve
In an ingress-protected fiber optic connector assembly, an optical fiber plug mates with a receptacle at a bulkhead adapter and an ingress-protected housing assembly couples to the bulkhead adapter to enclose the optical fiber plug. The ingress-protected housing includes an outer housing and a compressible cable seal. The outer housing is rotatable to advance the outer housing, simultaneously compressing the compressible cable seal and fastening the housing assembly to the bulkhead adapter. The outer housing can have a plurality coupling positions at which the cable seal is compressed with a different amount of compression force. A non-sealing cable clamp can transfer tension on the cable to the bulkhead adapter.
An optoelectronic module and optoelectronic connector assemblies can be used for releasable connection of a laser source to the module from a location exterior to the module. The construction of the optoelectronic connector assemblies is such that both in connection and disconnection, the electrical contacts are broken before the optical contacts so that the laser may power down before the optical connection is broken. The optoelectronic connection assemblies have blind mating features. Some versions are free of any latching or mechanical interconnection of the optoelectronic connector assemblies to each other. A spring has a construction which permits it to be received onto a cable by lateral movement of the spring.
An optoelectronic module and optoelectronic connector assemblies can be used for releasable connection of a laser source to the module from a location exterior to the module. The construction of the optoelectronic connector assemblies is such that both in connection and disconnection, the electrical contacts are broken before the optical contacts so that the laser may power down before the optical connection is broken. The optoelectronic connection assemblies have blind mating features. Some versions are free of any latching or mechanical interconnection of the optoelectronic connector assemblies to each other. A spring has a construction which permits it to be received onto a cable by lateral movement of the spring.
G02B 6/04 - Light guidesStructural details of arrangements comprising light guides and other optical elements, e.g. couplings formed by bundles of fibres
G02B 6/38 - Mechanical coupling means having fibre to fibre mating means
G02B 6/40 - Mechanical coupling means having fibre bundle mating means
An optical fiber connector assembly comprises at least one connector having a latching arm for coupling to an adapter, and a remote release tab having a protrusion configured to cooperate with the adapter to depress said latching arm when the remote release tab is pulled relative to the adapter. The optical fiber connector assembly may further be configured to allow reversing its polarity.
Devices and methods for connecting optical fibers are provided. In some embodiments, connectors and adaptors for two-fiber mechanical transfer type ferrules are disclosed. In some embodiments, MT connectors, such as simplex, duplex, and quad micro-MT adaptors are disclosed. In some embodiments, MT adaptors, such as simplex, duplex, and quad adaptors are disclosed. In some embodiments, optical fiber cables that modularly coupled with at least one optical fiber connector, adaptor, and other optical fiber cable the cable is configured to provide a remote release from an adaptor receptacle.
An optical connector holding one or more optical ferrule assembly is provided. The optical connector includes an outer body, an inner front body accommodating the one or more optical ferrule assembly, ferrule springs for urging the optical ferrules towards a mating receptacle, and a back body for supporting the ferrule springs. The outer body and the inner front body are configured such that four optical ferrule assembly are accommodated in a small form-factor pluggable (SFP) transceiver footprint or eight optical ferrule assembly are accommodated in a quad small form-factor pluggable (QSFP) transceiver footprint. A receptacle can hold one or more connector inner bodies forming a single boot for all the optical fibers of the inner bodies.
The clip for securing two fiber optic connectors may include a first engagement member having a top surface and a length; a second engagement member spaced apart from the first engagement member; and a linkage member extending between the first and second engagement members and connecting the first engagement member and the second engagement member. A space is defined between the first and second engagement members to house the connectors. The linkage member is configured to separate the two fiber optic connectors when they are sandwiched between the first and second engagement members.
A connection system may include fiber optic connectors and an optical receptacle into which the connectors are plugged. The fiber optic connectors are constructed so that the width of the connectors is small. Eight fiber optic connectors can be received in an opening of a QSFP style transceiver.
A fiber optic connector includes a housing having proximal and distal ends and a latch for securing the fiber optic connector to an adapter housing. A ferrule forms an optical connection with a second fiber optic connector. The ferrule is disposed distally of the housing. A spring holder operatively couples the ferrule to the housing. The spring holder is movable relative to at least one of the housing and the ferrule to enable the ferrule to move proximally and distally relative to the housing. A spring biases the ferrule in a distal direction away from the housing. The spring is mounted on the spring holder.
An optical connector holding two or more LC-type optical ferrules is provided. The optical connector includes an outer body, an inner front body accommodating the two or more LC-type optical ferrules, ferrule springs for urging the optical ferrules towards a mating receptacle, and a back body for supporting the ferrule springs. The outer body and the inner front body are configured such that four LC-type optical ferrules are accommodated in a small form-factor pluggable (SFP) transceiver footprint or eight LC-type optical ferrules are accommodated in a quad small form-factor pluggable (QSFP) transceiver footprint. A mating receptacle (transceiver or adapter) includes internal alignment slots configured to accept a corresponding alignment key on connector outer housing to ensure alignment and orientation for maximum signal transfer between opposing ferrule end faces.
Devices and methods for connecting optical fibers are provided. In some embodiments, connectors and adaptors for two-fiber mechanical transfer type ferrules are disclosed. In some embodiments, MT connectors, such as simplex, duplex, and quad micro-MT adaptors are disclosed. In some embodiments, MT adaptors, such as simplex, duplex, and quad adaptors are disclosed. In some embodiments, optical fiber cables that modularly coupled with at least one optical fiber connector, adaptor, and other optical fiber cable the cable is configured to provide a remote release from an adaptor receptacle.
An optical connector assembly a first structure and a second structure, the two structures secured together using a retention structure to form a hybrid assembly. The retention structure uses a slot apex located in a slot channel for securing at least one latch pin of a coupling nut to an adapter housing forming the ingress protected connector without the use of a bias spring. The hybrid assembly is designed to resist water or debris ingress, and may eliminate the use of a bias force to further resist separating the hybrid assembly.
Various embodiments disclosed herein are directed to a Network system including: a connector comprising a housing comprising a groove running widthwise on a surface of the housing; and a push-pull tab comprising a complementary groove, wherein the push-pull tab is detachably connected to the housing; and a receiver device comprising one or more ports for receiving the connector, the one or more ports having an interchangeable anchor device including a first portion and a second portion; wherein the groove is configured to receive the first portion of the interchangeable anchor device when the connector is inserted into the receiving element, and wherein the complimentary groove is configured to receive the second portion of the interchangeable anchor device when the connector is inserted into the receiving element, the push-pull tab being configured to disengage the second portion of the interchangeable anchor device from the complementary groove when the push-pull tab is moved in a direction away from the connector, thereby disengaging the first portion of the interchangeable anchor device from the grove of the connector. Other aspects are described and claimed.
A micro connector kit including a ferrule assembly, an optical sub-assembly ("OSA") and a micro connector. The ferrule assembly is coupled to an optical fiber and includes a ferrule. The OSA can receive an electric signal and transmit an optical signal or receive an optical signal and transmit an electric signal. The OSA includes a receptacle sized and shaped to receive the ferrule of the ferrule assembly to form an optical connection between the ferrule assembly and the OSA. The micro connector secures the optical connection between the ferrule assembly and the OSA. The micro connector includes a micro connector housing that forms a direct, mating connection with the OSA to secure the optical connection between the ferrule assembly and the OSA. The connection is made using only a very small space, allowing more ferrule assembly and OSA connections to be made in a smaller area.
The fiber optic adapter according to the present disclosure may include an adapter housing defining a channel to receive a fiber optic connector having one or more ferrules, and a first shutter and a second shutter attached to opposing sidewalls of the adapter housing. Each of the first and second shutters have a first member and a second member. The first member is configured to extend into the channel. the first members of the first and second shutters are sized and shaped to cooperatively close the channel. At least one of the first member is resiliently movable upon insertion of the fiber optic connector into the channel to open the channel. The fiber optic adapter may prevent the entry of the dust and other debris.
The fiber optic adapter according to the present disclosure may include an adapter housing defining a channel to receive a fiber optic connector having one or more ferrules, and a first shutter and a second shutter attached to opposing sidewalls of the adapter housing. Each of the first and second shutters have a first member and a second member. The first member is configured to extend into the channel. the first members of the first and second shutters are sized and shaped to cooperatively close the channel. At least one of the first member is resiliently movable upon insertion of the fiber optic connector into the channel to open the channel. The fiber optic adapter may prevent the entry of the dust and other debris.
An optical connector cleaning tool includes a fitting portion (44) fitted in the first or second hole (36, 37) of a connection component (32) into which a compact dual core optical connector is fitted on one end side and a cleaning medium (45) projecting from the fitting portion (44). The fitting portion (44) is formed to have a shape by which the fitting portion (44) is fitted in the first or second hole (36, 37) in each of the first and second postures as postures shifted through 180° with respect to as the center the middle (P2) of a virtual straight line connecting the centers of the two ferrules when viewed from an axial direction of the compact dual core optical connector. The fitting portion (44) contacts one ferrule in a state in which the fitting portion (44) is set in the first posture. The fitting portion (44) contacts the other ferrule in a state in which the fitting portion (44) is set in the second posture. There can be provided an optical connector cleaning tool by which the connection end faces of the compact dual core optical connector having two ferrules in one housing can be cleaned.
An outdoor rated ingress protected one-piece adapter with a first and second end. First end accepts a fiber optic adapter configured to accept a LC, SN, CS, SC or MPO fiber ferrule assembly. A second end accepts a cable gland assembly that secures a cable therein. The first end is configured to accept an outdoor rated connector having a fiber connector therein. The connector/adapter assembly is rated for outdoor use.
A multi-fiber, fiber optic connector may include a reversible keying arrangement for determining the orientation for plugging the connector into an adapter to thereby allow for a change in polarity of the connection to be made on site. The connector housing may be configured to engage with a removable key that may be engaged with the housing in at least two different locations to provide the plug-in orientation, or the housing may have slidably displaceable keys movable between multiple positions on the housing.
A fiber optic ferrule sub-assembly for insertion into an outer housing of a fiber optic connector includes a ferrule assembly having a ferrule that forms an optical communication connection with another fiber optic device. A back housing includes a back post to be attached to a fiber optic cable. A spring is operatively disposed between the ferrule assembly and the back housing. A linkage connects the ferrule assembly to the back housing such that the spring is compressed and biases the ferrule away from the back housing prior to insertion of the fiber optic ferrule sub-assembly into the outer housing.
To couple light between an optical fiber and a grating coupler of a photonic integrated circuits, a mirror is provided to turn light to/from the optical fiber to allow the axis of the optical fiber to be oriented at small angles or parallel to the surface of the PIC, and lowered close to the surface of the PIC. The mirror is further configured to reshape light from a flat polished optical fiber to produce a mode field resembling the mode field of an angled polished optical fiber, to match the design angle of existing grating couplers that are designed to work with angled polished optical fibers. The mirror and optical fiber alignment structure in the optical connector are integrally/simultaneous formed by precision stamping.
Narrow width fiber optic connectors having spring loaded remote release mechanisms to facilitate access and usage of the connectors in high density arrays. A narrow width fiber optic connector comprises a multi-fiber connector, wherein a width of said narrow width fiber optic connector is less than about 5.25 mm, a housing configured to hold the multi-fiber connector and further comprising a connector recess, and a pull tab having a ramp area configured to disengage a latch of one of an adapter and an SFP from said connector recess. The pull tab may include a spring configured to allow the latch of one of the adapter and the SFP to engage with the connector recess.
G02B 6/38 - Mechanical coupling means having fibre to fibre mating means
H01R 13/633 - Additional means for facilitating engagement or disengagement of coupling parts, e.g. aligning or guiding means, levers, gas pressure for disengagement only
90.
Ultra-small form factor optical connectors used as part of a reconfigurable outer housing
An optical connector holding one or more optical ferrule assembly is provided. The optical connector includes an outer body, an inner front body accommodating the one or more optical ferrule assembly, ferrule springs for urging the optical ferrules towards a mating receptacle, and a back body for supporting the ferrule springs. The outer body and the inner front body are configured such that four optical ferrule assembly are accommodated in a small form-factor pluggable (SFP) transceiver footprint or eight optical ferrule assembly are accommodated in a quad small form-factor pluggable (QSFP) transceiver footprint. A receptacle can hold one or more connector inner bodies forming a single boot for all the optical fibers of the inner bodies.
A multi-fiber, fiber optic connector may include a reversible keying arrangement for determining the orientation for plugging the connector into an adapter to thereby allow for a change in polarity of the connection to be made on site. The connector housing may be configured to engage with a removable key that may be engaged with the housing in at least two different locations to provide the plug-in orientation, or the housing may have slidably displaceable keys movable between multiple positions on the housing.
A behind-the-wall optical connector an outer housing configured to be inserted into an adapter with a corresponding inner surface, a ferrule included in an annular collar to mate with a corresponding projection at an adapter opening, and a latch attached to one side of housing configured to lock the connecter into an adapter opening. The latch is further configured with a locking channel and guide to accept a pull tab with a catch at one end, the pull tab releases the connector from the adapter opening when the tab is pulled rearward or away from the adapter.
Systems and methods of using a multiport assembly and associated components are disclosed, The multiport assembly can include a multiport device that communicatively couples multiple sets or pairs of connectors, such as optical connectors or electrical connectors, together. The multiport assembly can also include an auxiliary port device that couples to the multiport device to expand the capacity of the multiport assembly. Both the multiport and auxiliary port devices can be selectively configured to receive specific types of connectors by selectively coupling to different types of adapters, where the types of adapters correspond to the types of connectors. When coupled to the multiport or auxiliary port devices, the adapters facilitate the formation of the communication between its corresponding set of connectors.
H01R 11/11 - End pieces or tapping pieces for wires or cables, supported by the wire or cable and having means for facilitating electrical connection to some other wire, terminal, or conductive member
Systems and methods of using a multiport assembly and associated components are disclosed. The multiport assembly can include a multiport device that communicatively couples multiple sets or pairs of connectors, such as optical connectors or electrical connectors, together. The multiport assembly can also include an auxiliary port device that couples to the multiport device to expand the capacity of the multiport assembly. Both the multiport and auxiliary port devices can be selectively configured to receive specific types of connectors by selectively coupling to different types of adapters, where the types of adapters correspond to the types of connectors. When coupled to the multiport or auxiliary port devices, the adapters facilitate the formation of the communication between its corresponding set of connectors.
H01R 13/641 - Means for preventing, inhibiting or avoiding incorrect coupling by indicating incorrect couplingMeans for preventing, inhibiting or avoiding incorrect coupling by indicating correct or full engagement
H01R 13/645 - Means for preventing, inhibiting or avoiding incorrect coupling by exchangeable elements on case or base
H01R 24/54 - Intermediate parts, e.g. adapters, splitters or elbows
H01R 27/02 - Coupling parts adapted for co-operation with two or more dissimilar counterparts for simultaneous co-operation with two or more counterparts
Systems and methods of using a multiport assembly and associated components are disclosed. The multiport assembly can include a multiport device that communicatively couples multiple sets or pairs of connectors, such as optical connectors or electrical connectors, together. The multiport assembly can also include an auxiliary port device that couples to the multiport device to expand the capacity of the multiport assembly. Both the multiport and auxiliary port devices can be selectively configured to receive specific types of connectors by selectively coupling to different types of adapters, where the types of adapters correspond to the types of connectors. When coupled to the multiport or auxiliary port devices, the adapters facilitate the formation of the communication between its corresponding set of connectors.
G02B 6/38 - Mechanical coupling means having fibre to fibre mating means
H01R 27/02 - Coupling parts adapted for co-operation with two or more dissimilar counterparts for simultaneous co-operation with two or more counterparts
H01R 24/54 - Intermediate parts, e.g. adapters, splitters or elbows
G02B 6/40 - Mechanical coupling means having fibre bundle mating means
H01R 13/518 - Means for holding or embracing insulating body, e.g. casing for holding or embracing several coupling parts, e.g. frames
H01R 13/641 - Means for preventing, inhibiting or avoiding incorrect coupling by indicating incorrect couplingMeans for preventing, inhibiting or avoiding incorrect coupling by indicating correct or full engagement
H01R 13/52 - Dustproof, splashproof, drip-proof, waterproof, or flameproof cases
H01R 13/645 - Means for preventing, inhibiting or avoiding incorrect coupling by exchangeable elements on case or base
Systems and methods of using a multiport assembly and associated components are disclosed. The multiport assembly can include a multiport device that communicatively couples multiple sets or pairs of connectors, such as optical connectors or electrical connectors, together. The multiport assembly can also include an auxiliary port device that couples to the multiport device to expand the capacity of the multiport assembly. Both the multiport and auxiliary port devices can be selectively configured to receive specific types of connectors by selectively coupling to different types of adapters, where the types of adapters correspond to the types of connectors. When coupled to the multiport or auxiliary port devices, the adapters facilitate the formation of the communication between its corresponding set of connectors.
G02B 6/00 - Light guidesStructural details of arrangements comprising light guides and other optical elements, e.g. couplings
G02B 6/38 - Mechanical coupling means having fibre to fibre mating means
H01R 27/02 - Coupling parts adapted for co-operation with two or more dissimilar counterparts for simultaneous co-operation with two or more counterparts
H01R 24/54 - Intermediate parts, e.g. adapters, splitters or elbows
G02B 6/40 - Mechanical coupling means having fibre bundle mating means
H01R 13/518 - Means for holding or embracing insulating body, e.g. casing for holding or embracing several coupling parts, e.g. frames
H01R 13/641 - Means for preventing, inhibiting or avoiding incorrect coupling by indicating incorrect couplingMeans for preventing, inhibiting or avoiding incorrect coupling by indicating correct or full engagement
H01R 13/52 - Dustproof, splashproof, drip-proof, waterproof, or flameproof cases
H01R 13/645 - Means for preventing, inhibiting or avoiding incorrect coupling by exchangeable elements on case or base
An optical fiber connector assembly comprises at least one connector having a latching arm for coupling to an adapter, and a remote release tab having a protrusion configured to cooperate with the adapter to depress said latching arm when the remote release tab is pulled relative to the adapter. The optical fiber connector assembly may further be configured to allow reversing its polarity.
An integral fan-out connector assembly for fiber optic cables includes a connector housing that provides an integrated fan-out housing and connection adapter. The fan-out connector housing may be configured with a variety of cable adapters, and may be installed as a ‘plug and play’ type solution where it will be ready to accept a feed cable for use when needed. A bracket may support the fan-out system on a support structure as a pole. The bracket can facilitate plug-and-play use of the fan-out system.
An optical fiber connector assembly comprises at least one connector having a latching arm for coupling to an adapter, and a remote release tab having a protrusion configured to cooperate with the adapter to depress said latching arm when the remote release tab is pulled relative to the adapter. The optical fiber connector assembly may further be configured to allow reversing its polarity.
An optical connector holding one or more optical ferrule assembly is provided. The optical connector includes an outer body, an inner front body accommodating the one or more optical ferrule assembly, ferrule springs for urging the optical ferrules towards a mating receptacle, and a back body for supporting the ferrule springs. The outer body and the inner front body are configured such that four optical ferrule assembly are accommodated in a small form-factor pluggable (SFP) transceiver footprint or eight optical ferrule assembly are accommodated in a quad small form-factor pluggable (QSFP) transceiver footprint. A receptacle can hold one or more connector inner bodies forming a single boot for all the optical fibers of the inner bodies.
