The present disclosure relates generally to optical fiber communication systems. More particularly, the present disclosure relates to fiber optic connectors used in optical fiber communication systems.
Fiber optic communication systems are becoming prevalent in part because service providers want to deliver high bandwidth communication capabilities (e.g., data and voice) to customers. Fiber optic communication systems employ a network of fiber optic cables to transmit large volumes of data and voice signals over relatively long distances. Optical fiber connectors are an important part of most fiber optic communication systems. Fiber optic connectors allow two optical fibers to be quickly optically connected without requiring a splice. Fiber optic connectors can be used to optically interconnect two lengths of optical fiber. Fiber optic connectors can also be used to interconnect lengths of optical fiber to passive and active equipment. Fiber optic connectors can include single fiber connectors and multi-fiber connectors.
A typical fiber optic connector includes a ferrule assembly supported at a distal end of a connector housing. A spring is used to bias the ferrule assembly in a distal direction relative to the connector housing. The ferrule functions to support an end portion of at least one optical fiber (in the case of a multi-fiber ferrule, the ends of multiple fibers are supported). The ferrule has a distal end face at which a polished end of the optical fiber is located. When two fiber optic connectors are interconnected, the distal end faces of the ferrules abut one another and the ferrules are forced proximally relative to their respective connector housings against the bias of their respective springs. With the fiber optic connectors connected, their respective optical fibers are coaxially aligned such that the end faces of the optical fibers directly oppose one another. In this way, an optical signal can be transmitted from optical fiber to optical fiber through the aligned end faces of the optical fibers. For many fiber optic connector styles, alignment between two fiber optic connectors is provided through the use of an intermediate fiber optic adapter.
A fiber optic connector is often secured to the end of a corresponding fiber optic cable by anchoring strength members of the cable to the connector housing of the connector. Anchoring is typically accomplished through the use of conventional techniques such as crimps or adhesive. Anchoring the strength members of the cable to the connector housing is advantageous because it allows tensile load applied to the cable to be transferred from the strength members of the cable directly to the connector housing. In this way, the tensile load is not transferred to the ferrule assembly of the fiber optic connector. If the tensile load were to be applied to the ferrule assembly, such tensile load could cause the ferrule assembly to be pulled in a proximal direction against the bias of the connector spring thereby possibly causing an optical disconnection between the connector and its corresponding mated connector. Fiber optic connectors of the type described above can be referred to as pull-proof connectors.
A number of factors are important with respect to the design of a fiber optic connector. One aspect relates to ease of manufacturing and assembly. Another aspect relates to connector cost, durability, and reliability.
The present disclosure generally relates to a fiber optic connector having features that reduces the overall length of the connector. The present disclosure also relates to a fiber optic connector having features that reduces cost and the number of parts of the connector.
One aspect of the present disclosure relates to a fiber optic connector that can include a connector body assembly that defines a central longitudinal axis that extends between a front end and a rear end of the connector body assembly. The connector body assembly can have a connector body length that extends along the central longitudinal axis between the front and rear ends of the connector body assembly. The connector body assembly can also include a front connector body part including a front with a front end portion and a rear with a rear end portion, the front end portion can define a connector plug. The connector body assembly can further include a rear connector body part that defines a forward end and an opposite rearward end. The rearward end can include a rear portion that defines a fiber opening in alignment with the central longitudinal axis. The rear connector body part can be secured within the rear end portion of the front connector body part. The fiber optic connector can include a ferrule positioned at least partially within the connector body assembly. The ferrule can have a front end and an opposite rear end and a ferrule length that extends along the central longitudinal axis between the front and rear ends of the ferrule. The connector body length may be less than 2.0 times the ferrule length. The fiber optic connector can include a spring for biasing the ferrule in a forward direction. The spring can be retained within the connector body assembly by the rear connector body part.
Another aspect of the present disclosure relates to a fiber optic assembly that can include a fiber optic connector having a connector body assembly defining a central longitudinal axis that extends between a front end and a rear end of the connector body assembly. The connector body assembly can include a front connector body part having a front with a front end portion and a rear with a rear end portion, the front end portion defining a connector plug. The connector body assembly can include a rear connector body part that defines a forward end and an opposite rearward end. The rearward end can include a rear portion defining a fiber opening in alignment with the central longitudinal axis. The rear connector body part can have a rear connector body length that extends along the central longitudinal axis between the forward end and the rearward end of the rear connector body part and the rear connector body part can be secured within the rear end portion of the front connector body part. The fiber optic assembly can include a fiber optic adapter having a first axial end portion defining a first adapter port and a second axial end portion defining a second adapter port. The fiber optic adapter can have an adapter length that extends between the first and second axial end portions. The connector body assembly can be secured in the first adapter port of the fiber optic adapter and the rear connector body length may be less than 1.5 times the adapter port length.
A further aspect of the present disclosure relates to a fiber optic connector that can include a connector body assembly that defines a central longitudinal axis that extends between a front end and a rear end of the connector body assembly. The connector body assembly can have a connector body length that extends along the central longitudinal axis between the front and rear ends of the connector body assembly. The connector body assembly can also include a front connector body part including a front with a front end portion and a rear with a rear end portion, the front end portion can define a connector plug. The connector body assembly can further include a rear connector body part that defines a forward end and an opposite rearward end. The rearward end can include a rear portion that defines a fiber opening in alignment with the central longitudinal axis. The rear connector body part can be secured within the rear end portion of the front connector body part. The fiber optic connector can include a ferrule positioned at least partially within the connector body assembly. The ferrule can have a front end and an opposite rear end and a ferrule length that extends along the central longitudinal axis between the front and rear ends of the ferrule. The connector body length may be less than 2.0 times the ferrule length. The fiber optic connector can include a spring for biasing the ferrule in a forward direction. The spring can be retained within the connector body assembly by the rear connector body part. The fiber optic connector can include a release sleeve mounted over the connector body assembly. The release sleeve can extend from a first end to a second end such that the first end of the release sleeve is positioned nearer the front end of the connector body assembly and the second end of the release sleeve is positioned nearer the rear end of the connector body assembly.
Another aspect of the present disclosure relates to a fiber optic connector having a connector body with integral/unitary fiber bend radius protection.
A further aspect of the present disclosure relates to a fiber optic connector including a connector body defining a central longitudinal axis that extends in a front-to-rear orientation. The connector body includes a front connector housing piece and a rear connector housing piece that are both aligned along the central longitudinal axis. The front connector housing piece includes a front plug end and a rear plug end. The rear connector housing piece includes a front end and a rear end. The front end of the rear connector housing piece is adapted to connect with the rear plug end of the front connector housing piece. The rear end of the rear connector housing piece is configured to receive a fiber optic cable. The rear end of the rear connector housing piece includes a unitary fiber bend radius limiting structure. The unitary fiber bend radius limiting structure is generally funnel-shaped. The unitary fiber bend radius limiting structure flares radially outwardly from the central longitudinal axis along a curved profile as the unitary fiber bend radius limiting structure extends in a rearward direction. The fiber optic connector also including a ferrule assembly that mounts within the connector body. The ferrule assembly includes a ferrule, a ferrule hub mounted to a rear end of the ferrule, and a spring for biasing the ferrule and the ferrule hub in a forward direction. The ferrule assembly is captured between the front and rear connector housing pieces with the rear connector housing piece functioning as a rear spring stop. A front end of the ferrule is accessible at the front plug end of the front connector housing piece.
A variety of additional aspects will be set forth in the description that follows. The aspects relate to individual features and to combinations of features. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the broad inventive concepts upon which the embodiments disclosed herein are based.
In one example, the connector body assembly 22 includes a front connector body part 28 having a front end 30 with a front end portion 32 and a rear end 34 with a rear end portion 36. The front end portion 32 can define a connector plug 38. The connector body assembly 22 also includes a rear connector body part 40 (e.g., spring retainer) that defines a forward end 42 and an opposite rearward end 44. The rearward end 44 can include a rear portion 46 that defines a fiber opening 48 in alignment with the central longitudinal axis X.
Upon assembly, the rear connector body part 40 can be fully recessed within the front connector body part 28 such that the rear end 26 of the connector body assembly 22 is defined by the rear end 34 of the front connector body part 28 in which case the connector body length L1 is defined by the front connector body part 28. In certain examples, the rearward end 44 of the rear connector body part 40 can be flushed with the rear end 34 of the front connector body part 28 such that the connector body length L1 is defined by the front connector body part 28. It will be appreciated that a portion of the rear connector body part 40 may project outwardly from the rear end 34 of the front connector body part 28 in which case the connector body length would be defined by both the front connector body part 28 and the portion of the rear connector body part 40 that projects.
In one example, at least 75% of the rear connector body part 40 is within the connector body assembly 22. In other examples, at least 70% of the rear connector body part 40 is within the connector body assembly 22. In some examples, at least 80% of the rear connector body part 40 is within the connector body assembly 22. In one example, at least 90% or 100% of the rear connector body part 40 is within the connector body assembly 22. In other examples, the rear end 26 of the connector body assembly 22 can be defined by the rearward end 44 of the rear connector body part 40.
In one example, at least 70% of the rear connector body part 40 axially overlaps with the front connector body part 28. In some examples, at least 80% of the rear connector body part 40 axially overlaps with the front connector body part 28. In other examples, at least 90% of the rear connector body part 40 axially overlaps with the front connector body part 28. In still other examples, 100% of the rear connector body part 40 axially overlaps with the front connector body part 28. The front and rear connector body parts 28, 40 are illustrated and described in more detail with reference to
The example fiber optic connector 20 includes a ferrule 50 and an optical fiber 52 secured to the ferrule 50. The ferrule 50 can be positioned at least partially within the connector body assembly 22. In one example, the ferrule 50 is generally cylindrical. In one example, the ferrule 50 has a diameter in the range of 1-3 millimeters or in the range of 1.25-2.5 millimeters. Example ferrules include SC ferrules and LC ferrules. The ferrule 50 includes a front end 54 positioned opposite from a rear end 56. The front end 54 of the ferrule 50 includes an end face 64 at which an interface end 66 of the optical fiber 52 is located. The front end 54 of the ferrule 50 is positioned distally outwardly beyond the front end 30 of the front connector body part 28 and the rear end 56 of the ferrule 50 is positioned within the connector body assembly 22.
The ferrule 50 defines a ferrule bore 68 that extends through the ferrule 50 from the front end 54 to the rear end 56. The optical fiber 52 includes a first portion 70 secured within the ferrule bore 68 and a second portion 72 that extends rearwardly from the rear end 56 of the ferrule 50. The first portion 70 of the optical fiber 52 is preferably secured by an adhesive (e.g., epoxy) within the ferrule bore 68 of the ferrule 50. The interface end 66 preferably includes a processed end face accessible at the front end 54 of the ferrule 50. The ferrule 50 includes a ferrule hub 74 mounted to the rear end 56 of the ferrule 50. Upon assembly, the ferrule 50 can be captured between the front and rear connector body parts 28, 40. In one example, the front connector body part 28 and the rear connector body part 40 can be attached together by a snap-fit connection interface to capture the ferrule 50 and the ferrule hub 74 therebetween, alternatives are possible. Generally, the ferrule 50 and ferrule hub 74 are secured together by convenient methods including press fit or adhesive mounts. The fiber optic connector 20 can be one of a variety of well-known connector types, including SC, FC, ST, LX.5, LC, and others.
The ferrule 50 is preferably constructed of a relatively hard material capable of protecting and supporting the first portion 70 of the optical fiber 52. In one embodiment, the ferrule 50 has a ceramic construction. In other embodiments, the ferrule 50 can be made of alternative materials such as Ultem, thermoplastic materials such as Polyphenylene sulfide (PPS), other engineering plastics or various metals. In one example, the ferrule 50 can be a single fiber ferrule such as a ferrule for and SC connector, and ST connector, or an LC connector. While
The ferrule 50 has a ferrule length L2 that extends along the central longitudinal axis X between the front and rear ends 54, 56 of the ferrule 50. In certain examples, the rear connector body part 40 is shorter than the ferrule 50. In one example, the rear connector body part 40 is less than 75% the length L2 of the ferrule 50, alternatives are possible.
In one aspect, the connector body length L1 can be less than 2.0 times the ferrule length L2. In other aspects, the connector body length L1 can be 1.75 times the ferrule length L2. In some aspects, the connector body length L1 can be less than 1.75 times the ferrule length L2. In one example, the connector body length L1 of the connector body assembly 22 is less than 1.5 times the adapter port length L4. In one example, the connector body length L1 is less than 1.25 times the adapter port length L4.
The example fiber optic connector 20 includes a spring 58 for biasing the ferrule 50 and the ferrule hub 74 in a forward direction D1. The spring 58 can be retained within the connector body assembly 22 by the rear connector body part 40. The rear connector body part 40 defines a slot 61 so that the rear connector body part 40 can be loaded or slid on after assembly of the ferrule connector. Thus, rather than the rear connector body part 40 being threaded, can be dropped over the ferrule connector through the slot 61. The rear connector body part 40 defines a receptacle 60 (e.g., pocket) (see
The ferrule hub 74 includes a front portion 77 and a rear portion 78. The front and rear portions 77, 78 may each have hexagon shapes that are aligned together. The front portion 77 is a hex flange that can includes a series of flats 79 used for indexing or otherwise rotationally positioning the ferrule 50 in the front connector body part 28. The front connector body part 28 and the front portion 77 of the ferrule hub 74 can have mating geometries that allow the ferrule 50 to be mounted at a desired rotatable position. Indicia can be provided on one of the flats 79 so as to indicate a tuned position (e.g., core offset) of the first portion 70 of the optical fiber 52 within the ferrule 50. In this way, the ferrule 50 can be rotationally oriented within the front connector body part 28 taking tuning into consideration. Thus, the hex shape of the ferrule hub 74 and receptacle of the front connector body part 28 allows tuning by allowing core offset to be oriented at a desired position. The front portion 77 can be secured on the ferrule 50 prior to the stripping, cleaning, cleaving, active alignment, and splicing operations. In this way, front portion 77 can be used to facilitate handling of the ferrule 50 during such operations.
Typically in a ferrule, the fiber core is rarely perfectly centered within the ferrule due to manufacturing tolerances. The offset distance between the center of the fiber core and the center of the ferrule is the core offset. To optically connect two connectors, they are inserted into an adapter having an alignment sleeve that receives and co-axially aligns the ferrules. Ideally, the cores of the fibers are co-axially aligned so that light can be transmitted between the fibers. However, due to core offset, the cores may not be co-axially aligned. For example, a worse-case scenario is when the core offsets of connected ferrules are 180 degrees offset from one another.
In certain connectors, the connectors are “tuned” by identifying the direction of core offset, and then assembling the connectors so that the core offsets are always facing in the same direction (e.g., the twelve o'clock position). In this way, when two connectors are mated, the core offsets are aligned and the worse-case scenario of the core offsets being 180 degrees offset from one another will not occur. In an APC (i.e., angle polish connector), the core offset is taken into consideration so that the direction of the core offset is oriented at a predetermined position relative to the direction of the angle polish to provide a tuning function.
Referring now to
In one example, the ferrule hub 74 and the ferrule 50 are two separate parts. In other examples, the ferrule hub 74 and the ferrule 50 are formed as a single piece. In other words, the ferrule hub 74 and ferrule 50 are a single, integrally molded piece. The internal passage 82 is sized to receive a terminal end of a fiber optic cable 84, including a portion of the optical fiber 52 and jacket.
In some examples, the optical fiber 52 and/or the jacket can be fixed within the internal passage 82 using various methods, such as by an adhesive. In other examples, one or both of the optical fiber 52 and the jacket are retained within the internal passage 82 by a frictional fit.
In certain examples, the ferrule hub 74 and ferrule 50 is manufactured of a polymeric material using a molding process. In one example, the ferrule hub 74 and ferrule 50 is made of Polyphenylene Sulfide (PPS) using an injection molding process. Other materials and molding processes can be used.
The example fiber optic assembly 10 can include a fiber optic adapter 90 that has a first axial end portion 92 defining a first adapter port 94 and a second axial end portion 96 defining a second adapter port 98. The fiber optic adapter 90 has an adapter length L3 that extends between the first and second axial end portions 92, 96. The connector body assembly 22 is secured in the first adapter port 94 of the fiber optic adapter 90. The first adapter port 94 has an adapter port length L4.
Referring to
Referring to
The front connector body part 28 includes a sliding surface 104 (e.g., slide guide) and the retractable release sleeve 76 includes a sliding surface 106 (e.g., slide). The sliding surface 106 of the retractable release sleeve 76 can slidingly engage the sliding surface 104 of the front connector body part 28 between a latching position and a release position. The retractable release sleeve 76 is mounted within the fiber optic adapter 90.
The retractable release sleeve 76 can be slid back and forth relative to the connector body assembly 22 through a limited range of movement that extends in a direction along the central longitudinal axis X. The retractable release sleeve 76 includes release ramps 17 that are used to disengage the retractable release sleeve 76 from the fiber optic adapter 90. A sleeve mount arrangement 71 is located within the fiber optic adapter 90. One example sleeve mount arrangement 71 is shown in
When the connector body assembly 22 is fully inserted into the fiber optic adapter 90 at one of the ports 94, 98, the flexible latching hooks 73 of the sleeve mount arrangement 71 engage the slots 91 defined in the outer portion 93 of the retractable release sleeve 76 to releasably hold connector body assembly 22 at the fiber optic adapter 90. For example, the latching hooks 73 may flex over ridges 95 and snap into the detents 97 of the front connector body part 28. When properly positioned within the fiber optic adapter 90, an optical connection is formed between an optical fiber of a first connector and an optical fiber of a second connector through the abutting contact faces of the ferrules.
When removing one of the fiber optic connectors, the slidable outer portion 93 of the retractable release sleeve 76 is slid axially relative to the front connector body part 28 away from the opposing connector until the flexible latching hooks 73 of the sleeve mount arrangement 71 are released from the slots 91 defined on the outer portion 93 of the retractable release sleeve 76.
The retractable release sleeve 76 includes finger tabs 75 positioned at the second end 102 of the retractable release sleeve 76. The finger tabs 75 can be gripped when it is desired to remove the fiber optic connector 20 from a given one of the ports 94, 98. For example, by pulling back (i.e., in a direction toward the rear end 26 of the connector body assembly 22) on the retractable retention sleeve 76 while the fiber optic connector 20 is mounted in a given port 94, 98, the release ramps 17 force the resilient tabs 89 apart from one another a sufficient distance to disengage the retractable release sleeve 76 from the fiber optic adapter 90. The retractable release sleeve 76 includes a keying rail 81 that fits within keying slots 83 of the fiber optic adapter 90 to ensure proper rotational alignment of the fiber optic connector 20 within the fiber optic adapter 90. When two connectors are latched within the ports 94, 98 of the adapter 90, the ferrules of the connectors fit within respective first and second ends 85 of a split sleeve 87 and are thereby held in co-axial alignment with one another.
The retractable release sleeve 76 is shown having a release sleeve length L6 that extends along the central longitudinal axis X between the first and second ends 100, 102. In one example, the release sleeve length L6 is less than 1.5 times the adapter port length L4. In one example, the release sleeve length L6 is less than 1.25 times the adapter port length L4. In certain embodiments, the release sleeve length L6 is less than 1.5 times the ferrule length L2. In certain embodiments, the release sleeve length L6 is less than 2.0 times the ferrule length L2.
Referring to
Referring again to
In one example, the rear connector body part 40 includes a fiber bend radius limiting structure 122 for providing bend radius protection. As such, the fiber bend radius limiting structure 122 can provide the function typically provided by a separate flexible boot. The fiber bend radius limiting structure 122 can be relatively rigid as compared to the flexibility of a standard connector boot. In certain examples, the fiber bend radius limiting structure 122 can aid in relieving the stress that would be imposed on the fiber optic cable 84 as it exits the fiber optic connector 20 without causing the fiber optic cable 84 to kink as it exits, which in most cases would exceed the maximum bend radius of the cable 84 causing damage to the optical fibers 52 therein or causing unacceptable signal loss.
In one example, the fiber bend radius limiting structure 122 is generally funnel-shaped and defines the fiber opening 48 at the rear portion 46 of the rear connector body part 40. The fiber bend radius limiting structure 122 can taper outwardly as the fiber bend radius limiting structure 122 extends in a rearward direction D2. The fiber bend radius limiting structure 122 can have a convex curvature as the fiber bend radius limiting structure 122 extends in the rearward direction D2. In certain examples, at least a portion of the fiber bend radius limiting structure 122 is axially coextensive within a portion of the front connector body part 28.
The fiber bend radius limiting structure 122 can be manufactured by various techniques. Suitable manufacturing techniques include injection molding or co-injection molding where multiple polymers of different moduli and different flexural characteristics can be used. One advantage of the co-injection molding would be that it may produce an extension having varying elastic moduli and flexural characteristics. The fiber bend radius limiting structure 122 may be integral with (e.g., formed in one seamless piece with) or coupled to, the rear connector body part 40, although alternatives are possible.
In one example, the rear connector housing piece 206 includes an example unitary fiber bend radius limiting structure 220. The example unitary fiber bend radius limiting structure 220 may be integral with (e.g., formed in one seamless piece with) or coupled to, the rear connector housing piece 206, although alternatives are possible. In one example, the rear connector housing piece 206 can be a unitary molded plastic part. The unitary fiber bend radius limiting structure 220 can be relatively rigid as compared to the flexibility of a standard connector boot. The example fiber bend radius limiting structure 220 is depicted as having a funnel-shape, although alternatives are possible. The example fiber bend radius limiting structure 220 may be configured to flare radially outwardly from the central longitudinal axis 208 along a non-linear profile 222 (e.g., curved profile) (see
The example unitary fiber bend radius limiting structure 220 provides bend radius protection for the optical fiber structure 218. As such, the example unitary fiber bend radius limiting structure 220 of the rear connector housing piece 206 can provide the function typically provided by a separate flexible boot. Thus, the fiber optic connector 200 may not include a protective, flexible boot at the rear end 216 of the rear connector housing piece 206. The optical fiber structure 218 can bend along the non-linear profile 222 or constant radius of curvature, preferably at a radius that does not violate the minimum bend radius of the optical fiber structure 218. Through the use of the example unitary fiber bend radius limiting structure 220, the optical fiber structure 218 can bend at the constant non-linear profile 222 or radius of curvature, desirably at a radius that is greater than the minimum bend radius of the optical fiber structure 218.
In certain examples, the example unitary fiber bend radius limiting structure 220 also aids in relieving the stress that would be imposed on the optical fiber structure 218 as it exits the fiber optic connector 200 without causing the optic fiber structure 218 to kink as it exits, which in most cases would exceed the maximum bend radius of the optical fiber structure causing damage to the optical fiber structure causing unacceptable signal loss.
Although alternatives are possible, the example unitary fiber bend radius limiting structure 220 has a somewhat conical shape with a taper forming portion 224 (see
Typically, the first cross-dimension D3 is at least 0.5 times the second cross-dimension D4. Usually, the first cross-dimension D3 is at least 2.0 times the second cross-dimension D4. Often, the first cross-dimension D3 is no more than 3.0 times the second cross-dimension D4. Of course, alternate ratios of the first cross-dimension D3 to the second cross-dimension D4 of the example unitary fiber bend radius limiting structure 220 are possible in many applications.
Referring to
Example materials used for forming the unitary fiber bend radius limiting structure 220 include metal or relatively hard plastic, such as polycarbonate, polyetherimide or polybutylene terephthalate.
The unitary fiber bend radius limiting structure 220 can be manufactured by various techniques. Suitable manufacturing techniques include injection molding or co-injection molding where multiple polymers of different moduli and different flexural characteristics can be used. One advantage of the co-injection molding would be that it may produce an extension having varying elastic moduli and flexural characteristics.
Still referring to
Referring to
As so arranged, the spring 240 is configured to bias the ferrule 232 in a distal direction 248 relative to the connector body 202. Accordingly, the ferrule 232 is movable in a proximal direction 250 relative to the fiber optic connector 200 from a distal (See
Still referring to
In other examples, the optical fiber structure 218 can include a fiber optic cable including a jacket, protective buffer layers and one or strength members for providing compressive and/or tensile reinforcement to the fiber optic cable.
The rear connector housing piece 206 defines a through-passage 252 that extends through the rear connector housing piece 206 from the rear end 216 to the front end 214. The rear connector housing piece 206 can function as a rear spring stop 254. The rear spring stop 254 can abut against a proximal end 256 (see
Turning again to
As shown, the catches 258 of the example rear connector housing piece 206 are arranged and configured to engage the retention arrangement 262 of the example front connector housing piece 204. The catches 258 and the retention arrangement 262 cooperate to define an axial insertion/retention interface between the front connector housing piece 204 and the rear connector housing piece 206. For example, the retention arrangement 262 of the front connector housing piece 204 can help to prevent the rear connector housing piece 206 from being proximally withdrawn therefrom.
To assemble the fiber optic connector 200, the ferrule assembly 230 is initially loaded into the front connector housing piece 204 by inserting the ferrule assembly 230 through the rear plug end 212 of the front connector housing piece 204. The optical fiber 244 of the fiber optic cable 218 can be secured within the ferrule 232 prior to loading the ferrule assembly 230 into the front connector housing piece 204. Also, the spring 240 and the rear connector housing piece 206 can be slid over the fiber optic cable 218 prior to securing the optical fiber 244 in the ferrule 232.
Once the ferrule assembly 230 has been loaded into the front connector housing piece 204, the rear connector housing piece 206 is aligned along the axis 208 and oriented relative to the front connector housing piece 204 such that the catches 258 of the rear connector housing piece 206 align with the retention arrangement 262 of the front connector housing piece 204. The rear connector housing piece 206 is then moved distally along the axis 208 relative to the front connector housing piece 204 such that the front end 214 of the rear connector housing piece 206 is inserted through the rear plug end 212 of the front connector housing piece 204 to be connected together.
Internal clearance is provided between the front connector housing piece 204 and the rear connector housing piece 206 to allow the rear connector housing piece 206 to be inserted without obstruction to the catches 258. For example, as the front end 214 of the rear connector housing piece 206 is inserted into the front connector housing piece 204, the catches 258 pass through gaps 264 and the until the catches 258 reach the retention arrangement 262 and are engaged therein. The rear spring stop 254 engages the spring 240 such that the spring 240 is compressed. A distal end 266 (see
From the forgoing detailed description, it will be evident that modifications and variations can be made without departing from the spirit and scope of the disclosure.
This application is a Continuation of U.S. patent application Ser. No. 15/760,188, filed on Mar. 14, 2018, now U.S. Pat. No. 10,520,683; which is a National Stage Application of PCT/EP2016/071518, filed on Sep. 13, 2016; which claims the benefit of U.S. Patent Application Ser. No. 62/218,244, filed on Sep. 14, 2015; U.S. Patent Application Ser. No. 62/383,090, filed on Sep. 2, 2016; and U.S. Patent Application Ser. No. 62/268,067, filed on Dec. 16, 2015, the disclosures of which are incorporated herein by reference in their entireties. To the extent appropriate, a claim of priority is made to each of the above disclosed applications.
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