BR102023002811A2 - FIBER OPTICAL RECEPTACLE THAT HAS AN ALIGNMENT ASSEMBLY - Google Patents

Abstract

A fiber optic receptacle includes a receptacle housing that defines an internal cavity opening through an internal end and an opposing external end; an alignment assembly disposed within the internal cavity defined by the receptacle housing and received through the internal end, wherein the alignment assembly comprises a plurality of alignment brackets and an alignment sleeve having ends contained within each alignment bracket; and a retainer for retaining the alignment assembly within the internal cavity defined by the receptacle housing, wherein the retainer has an opening and a plurality of prongs disposed around the opening.

Description

FIBER OPTICAL RECEPTACLE THAT HAS AN ALIGNMENT ASSEMBLY Related Requests

[0001] This application claims the priority benefit of Provisional Application Serial No. US 63/310,479, filed on February 15, 2022, the contents of which are relied upon and incorporated herein by reference in its entirety.

Background

[0002] The present disclosure generally relates to fiber optic receptacles for interconnecting optical fibers within a communications network.

[0003] Fiber optic networks have revolutionized the telecommunications industry, in part, due to the high bandwidth transport capacity, low signal degradation and low energy usage of fiber optic networks. As a result, fiber optic networks were created and expanded to provide “fiber-to-the-curb” (FTTC), “fiber-to-the-business” (FTTB), “fiber-to-the-home” (FTTH) , “fiber-to-the-premises” (FTTP) and “fiber-to-the-subscriber” (FTTS). Together, each of these is referred to generically as “FTTx”. To provide service to one of these subscriber locations, fiber optic networks must include a large number of interconnection points at which optical fibers are connected or optically combined in the field. In more recently developed fiber optic networks, communications service providers are demanding factory-ready interconnection solutions, commonly called “plug-and-play” systems, that are robust enough for use in field applications. Plug-and-play systems allow less-skilled field technicians to readily make optical interconnections, thereby reducing field labor costs and the time required to install and activate optical networks.

[0004] Factory-prepared interconnect solutions must not only properly align the corresponding optical fibers, but also protect the corresponding optical fibers against adverse environmental and mechanical influences such as moisture ingress and tensile forces, and more particularly protect the assembly of the receptacle (i.e. alignment assembly, etc.) in which the optical fibers are interconnected. Conventional fiber optic receptacles include a receptacle housing that defines an internal cavity that houses an alignment assembly for aligning opposing optical connectors or opposing ferrules. The alignment assembly is typically inserted into the front of the receptacle and is designed to receive a pair of ferrules, each of which is mounted to the end portions of one or more optical fibers. The alignment assembly assists in the rough alignment of the ferrules, and the ferrule guide pins or other alignment means assist in the detailed alignment of the optical fibers positioned on the end faces of the opposing ferrules. One of the ferrules is attached to the ends of one or more optical fibers extending from a cable, ribbon, or fiber-optic device and directed toward the rear of the receptacle, such as from the interior of an optical connection terminal or conventional containment. The other ferrule is mounted on one or more optical fibers that terminate in a fiber optic plug that is routed to the front of the receptacle, for example, a connectorized drop cable that leads to an optical network subscriber.

[0005] In the process of mating opposing ferrules within the receptacle, the plug ferrule is inserted into one end of the alignment assembly. Original receptacle designs required that the plug ferrule be retained within the alignment assembly by mechanical coupling, such as through a pair of latches. Although the latches effectively secure the plug ferrule within the alignment assembly, the mechanical coupling disadvantageously limits flotation between the plug ferrule and the alignment assembly. Recent receptacle designs include a biasing member, e.g., one or more linear springs, to provide flotation. Through testing of these receptacle designs, it was determined that the bias springs are subject to deformation during loading and ferrule insertion. To avoid this, changes to the structural design are necessary to control spring displacement and thus prevent buckling. A new design is also needed to facilitate assembly by allowing a “loose” fit between the bias springs and guide frames, and between the bias springs and the holes into which the bias springs are inserted. A receptacle design that controls spring displacement, prevents deformation, and provides a loose fit would prevent damage to bias springs during assembly and use.

[0006] A possible advantage associated with existing receptacle designs is that they allow access to the alignment assembly and rear (i.e. internal) ferrule from the outside of the connection terminal or housing without entering the connection terminal. connection or confinement, referred to in this document as “external access”. To achieve this, the receptacle is designed in two pieces as viewed from the front (i.e., outside) side of the receptacle with the alignment assembly held within the receptacle housing (first piece) by a second piece that is secured to the first piece and removable from outside the connection or confinement terminal. An example of such an external two-piece design is the fiber optic receptacle described and shown in US Patent No. 6,579,014 entitled “Fiber Optic Receptacle”. However, such a two-piece exterior design requires an extra seal between the first piece and the second piece to prevent water ingress. Additionally, the seal must be strong enough to prevent connector failure due to the freeze/thaw cycle that causes the second part to separate from the first. Additionally, a two-piece exterior design requires rigorous control and maintenance of high-quality molded surfaces. As mentioned previously, the two-piece external design provides the field technician access to the alignment assembly and rear ferrule. Consequently, although it is advantageous to eliminate the two-piece outer design and extra seal, a one-piece outer design also eliminates the ability to access the alignment assembly and rear ferrule from the front side of the receptacle. However, a one-piece external design allows the receptacle assembly to pass freeze/thaw cycle testing and provides additional improvements regarding ferrule and fiber optic alignment, which is especially important when combining hard contact connectors. angular (APC) for low loss requirements.

Brief Description

[0007] To achieve the foregoing, and in accordance with the purposes as embodied and broadly described herein, the present disclosure provides various embodiments of a fiber optic receptacle assembly and, more particularly, a fiber optic receptacle with alignment improved. Thus, the present disclosure provides a fiber optic receptacle designed to align and readily mate any similar pair of opposing optical connectors or ferrules precisely and securely, while also providing strain relief against pulling forces of up to about 600 lb/ft.

[0008] According to one aspect, a fiber optic receptacle includes a receptacle housing defining an outer end, an inner end, and an inner cavity for housing an alignment assembly operable for interconnecting such as optical connectors or ferrules. The receptacle housing allows insertion and removal of the alignment assembly from only the inner end, or back, of the housing, thereby eliminating removal of the alignment assembly from the outer end, or front side, of the receptacle. The alignment assembly is retained within the internal cavity by means of a retainer that is secured to the internal end of the receptacle housing. The alignment assembly is removed from the internal cavity by completely removing the retainer.

[0009] According to another aspect, an optical fiber receptacle including a receptacle housing, a retainer and an alignment assembly for receiving and aligning optical connectors or ferrules. The receptacle housing allows the alignment assembly to be inserted and removed only from the rear of the receptacle, compared to a conventional two-piece external design in which the alignment assembly is removed from the front of the receptacle to allow access to the assembly alignment and the rear ferrule. The fiber optic receptacle can be secured within a wall of an enclosure or can be used as a stand-alone receptacle assembly. The alignment assembly defines a passage opening extending longitudinally through opposing first and second ends that is adapted to receive a plug ferrule contained or partially contained within a first fiber optic connector and a second end adapted to receive a rear ferrule contained or partially contained within a second fiber optic connector. The receptacle housing includes opposing outer and inner ends, wherein the outer end is adapted to receive the plug ferrule and the inner end is adapted to receive the alignment assembly and rear ferrule. A retainer adjacent to the inner end of the receptacle housing buoyantly retains the alignment assembly within an internal cavity of the receptacle. The retainer and receptacle housing define tapered bias member supports for supporting one or more linear bias springs that operatively engage the alignment assembly so as to urge the alignment assembly toward the outer end of the receptacle housing. The alignment assembly defines a chamfer at its second end as a means for guiding the rear ferrule into the alignment assembly. The retainer defines a plurality of internal alignment tangs that provide a loose fit to facilitate alignment of the back ferrule and plug ferrule within the alignment assembly.

[0010] Typically, the fiber optic receptacle provides strain relief to an optical connection terminal or confinement so that one or more optical fibers of a fiber optic cable can be aligned and optically interconnected with one or more optical fibers routed to the receptacle from within the connecting or confining terminal. In one embodiment, the fiber optic receptacle includes a receptacle housing with an inner end and an outer end and an alignment assembly that is angled toward the outer end of the housing. The alignment assembly is polarized so that when a fiber optic plug ferrule is inserted into the outer end of the receptacle housing, the end face of the plug ferrule maintains physical contact with the end face of a rear ferrule positioned within the assembly of alignment without requiring the plug ferrule to be locked into the alignment assembly, providing flotation between the respective ferrules. According to another embodiment, a universal fiber optic receptacle is provided wherein an internal cavity defined by the receptacle housing and associated retainer are sized to receive any alignment assembly or optical connector, such as, for example, alignment assemblies configured to receiving and aligning a plurality of types of optical connectors or ferrules including MTP, MTRJ, SCDC, SC, DC, LC and the like.

Brief Description of the Drawings

[0011] These and other features, aspects and advantages disclosed in this document are better understood when the following detailed description is read with reference to the attached drawings, in which:

[0012] Figure 1 is an assembled view of a fiber optic receptacle in accordance with exemplary embodiments disclosed herein in substantial alignment with a fiber optic connector;

[0013] Figure 2 is an exploded view of the fiber optic receptacle shown in Figure 1 in accordance with exemplary embodiments disclosed herein in substantial alignment with the fiber optic connector shown in Figure 1;

[0014] Figure 3 is an exploded view of the fiber optic receptacle shown in Figure 1 in accordance with exemplary embodiments disclosed herein;

[0015] Figures 4, 5A and 5B are cross-sectional views of the fiber optic receptacle shown in Figure 1;

[0016] Figure 6 is an assembled view of an alignment assembly included in the fiber optic receptacle of Figure 1;

[0017] Figure 7 is an exploded view of an alignment assembly shown in Figure 6;

[0018] Figure 8A is a top view of the alignment assembly shown in Figure 6;

[0019] Figure 8B is a side view of the alignment assembly shown in Figure 6;

[0020] Figure 8C is a bottom view of the alignment assembly shown in Figure 6.

[0021] Figure 8D is another side view of the alignment assembly shown in Figure 6;

[0022] Figure 9A is a top view of an assembled fiber optic receptacle;

[0023] Figure 9B is a side view of the assembled fiber optic receptacle shown in Figure 9A;

[0024] Figure 9C is a bottom view of the assembled fiber optic receptacle shown in Figure 9A; It is

[0025] Figure 9D is another side view of the assembled fiber optic receptacle shown in Figure 9A;

Detailed Description

[0026] The embodiments will now be described more fully below with reference to the attached drawings. However, each embodiment can be shown in many different forms and should not be construed as limited to the embodiments set forth herein. These exemplary embodiments are provided so that this disclosure is thorough and complete and fully conveys the scope of the invention to those skilled in the art. Similar reference numbers may refer to similar elements throughout the various drawings.

[0027] The various embodiments described below provide a fiber optic receptacle with a design that eliminates the need for an internal seal, while allowing access to an alignment assembly from the rear of the receptacle. The design is an improvement over previous designs that allow the receptacle assembly to pass freeze/thaw cycle testing. The design also offers additional improvements regarding ferrule and optical fiber alignment, which is especially important when combining angular physical contact (APC) connectors for low-loss requirements. Embodiments of the fiber optic receptacle further provide an improved retainer and an improved alignment assembly. Thus, each embodiment provides a fiber optic receptacle designed to easily align and mate any similar pair of opposing optical connectors or ferrules in a precise and sealed manner, while providing strain relief against pulling forces of up to about 600 lb/ft.

[0028] The fiber optic receptacle interconnects optical fibers within a communications network. The receptacle is designed so that it can be mounted within an optical connection terminal, enclosure, or similar enclosure defining an opening or port in a wall through which one or more optical fibers are routed. The receptacle may also be mounted within an optical connection terminal, enclosure, pedestal, network interface device, or similar enclosure. In other embodiments, due to the robust (i.e., rugged) nature of its structure, the receptacle may be used in buried network installations. The fiber optic receptacle can also be used as a generic receptacle assembly and does not need to be mounted inside any wall of any enclosure. If mounted inside a wall, however, a rigid receptacle housing boss and coupling nut secure the receptacle to the wall, thus providing superior strain relief for pulling forces, up to about 600 lb/ft, compared to conventional receptacle assemblies.

[0029] In the exemplary embodiments shown and described herein, the fiber optic receptacle is adapted to receive a corresponding fiber optic plug with a plug ferrule mounted on the end of a fiber optic cable comprising one or more optical fibers for optically connect one or more optical fibers to a corresponding ferrule on the back of the receptacle (i.e., ferrule on the back). As used herein, the fiber optic cable associated with the fiber optic plug is referred to as a “drop cable” and is intended to include all types of fiber optic cables, such as, without limitation, a branch cable, a distribution cable, an extended distribution cable, a flat dielectric drop cable, a figure-eight drop cable or a shielded drop cable. Drop cable typically comprises between one and about twelve optical fibers, depending on the type of cable and the number and type of optical connectors. The particular components of the fiber optic receptacle and fiber optic plug described herein can be modified to accommodate different types of optical cables and connectors. As used herein, the term "optical fiber" is intended to include all types of single-mode and multimode light waveguides, including one or more bare optical fibers, coated optical fibers, loose-tube optical fibers, optical fibers compressed fibers, optical fibers in tape or any other means of transmitting light signals.

[0030] Each embodiment of fiber optic receptacle provides a design that prevents moisture and contaminants from reaching the end faces of the plug ferrule and the back ferrule. In all embodiments in which the receptacle is mounted in an opening or hole within a wall, a gasket provides a seal between the internal and external environments defined by the wall. Generally speaking, most of the components of the fiber optic receptacle and fiber optic plug are formed from a suitable polymer. Preferably, the polymer is a UV stabilized polymer. However, other suitable materials can also be used. For example, stainless steel or any other suitable metal may be used for various components of the receptacle and/or plug.

[0031] Referring now to Figures 1-3, an optical fiber receptacle 20 is shown in accordance with exemplary embodiments disclosed herein. Figures 2-3 show the fiber optic receptacle 20 in an exploded or disassembled configuration, while Figure 1 shows the fiber optic receptacle 20 in an assembled configuration. The receptacle 20 is preferably mounted within an opening or door in a wall of a containment (not shown) to connect optical fibers from outside the containment with optical fibers from within the containment. Figure 1 further illustrates how the fiber optic receptacle can be aligned with a fiber optic connector 100. However, the fiber optic receptacle 20 can be designed to accommodate and mate with any type of fiber optic connector with a plug. optical fiber that is mounted on the end portion of a fiber optic cable.

[0032] As shown, particularly with reference to Figures 2-3, the receptacle 20 includes a receptacle housing 22 that defines an internal cavity 24 that opens through opposing ends. The opposing ends include a first outer end 25a and a second inner end 25b. Typically, the opening through the outer end is sized to accommodate a mating fiber optic connector having a fiber optic plug. The outer end also includes threads 27a, 27b1, 27B2 and a notch 28, which facilitate connection to elements in a connector and/or other components. In preferred embodiments, the relatively large opening of the outer end allows the alignment assembly and the end face of a rear ferrule to be cleaned with a cleaning tool such as a cotton swab (e.g., Q-tip) or similar device. This is advantageous since the receptacle, unlike the fiber optic plug, can be exposed to harsh environmental conditions and possibly accumulate contaminants while not being used for an extended period of time. The various embodiments shown and described in this document allow for easy cleaning and better access without disassembly. Additionally, the outer end 25a of the receptacle 20 may be equipped with a dummy plug or dust cap when not in use to reduce the possibility of contaminant accumulation within the inner cavity 24.

[0033] As shown particularly in Figure 4, 5A, 5B, 6, 7, 8A-8D and 9A-9D, the alignment assembly 30 includes two alignment supports 34 (a proximal alignment support), 40 (a distal alignment) and includes elements that extend outward from opposite sides. Although the brackets 34, 40 may include flexible support features, each bracket is also used to align the alignment assembly 30 within the internal cavity 24 of the receptacle housing 22. The brackets 34, 40 extend so that they rest within guide channels defined within the internal cavity 24 of the receptacle housing 22. The receptacle housing 22 is preferably sized to define one or more guides extending longitudinally therethrough. Thus, the first end of the alignment assembly 30 can be positioned within the receptacle housing 22. Additionally, the brackets 34, 40 provide "keying" and "guiding" functions that prevent the alignment assembly 30 from being incorrectly loaded into the receptacle housing 22. Brackets 34, 40 further help prevent alignment assembly 30 from being withdrawn through the opening defined by retainer 46.

[0034] The distal alignment bracket 40 is configured for engagement with the retainer 46, while the proximal alignment bracket 34 is configured for engagement with the receptacle housing 22, as shown particularly in relation to Figures 4, 5A and 5B. Referring particularly to Figures 6-8B, the alignment assembly 30 includes an alignment sleeve 32, the proximal alignment bracket 34 and the distal alignment bracket 40. The alignment sleeve 32 is preferably in the form of a tube with at least a longitudinally extending groove 31 extending fully between the ends of the sleeve 33a, 33b and in quick-fit engagement with the alignment brackets. The alignment sleeve 32 is preferably manufactured from a ceramic material or one or more materials having similar properties. The proximal alignment support 34 includes a support base 35 with cutouts 36, a sleeve retaining member 37, which is cantilevered. The sleeve retaining member 37 is preferably integrally coupled to the support base 35 and a through hole HP extends through the support base 35 to the end of the retaining member 38. The proximal alignment support 34 additionally includes keying and guide members 42 , 44 which further facilitate engagement with the retainer 46 and the distal alignment bracket 40. Each keying and guiding member preferably includes a tang member 42t, 44t that fits into a corresponding opening or cutout in a member. coupling. As shown, the distal alignment support 40 includes a support base 41 having a plurality of cutouts arranged therein 42 and a sleeve retaining member 43, which is also cantilevered and integrally coupled to the support base 41. The retaining member of sleeve 43 also includes a through hole HD extending through the support base 41 to the end of retaining member 45.

[0035] When fully assembled, the alignment assembly forms a passage that extends longitudinally. The alignment assembly 30 is further configured to receive and align with a rear ferrule mounted on the ends of one or more optical fibers routed to the receptacle 20 from within the enclosure wall with a plug ferrule of a fiber optic plug mounted on the ends of one or more optical fibers of a fiber optic cable. In this aspect, the fiber optic plug ferrule may be inserted through the outer end of the receptacle 20 into the opening defined by the first end of the alignment assembly 30, while the rear ferrule is inserted through the inner end of the receptacle 20 into the opening defined by the second. end of alignment assembly 30.

[0036] The receptacle housing 22 may be sized and configured in any suitable manner. In the embodiments shown, the receptacle housing 22 comprises a cylindrical portion defining the internal cavity 24 and a flanged portion 26 located medially along the length of the housing 22, preferably closer to the external end. The flanged portion 26 extends radially outwardly from the receptacle housing 22 and may define a generally flat surface for receiving a sealing member. A generally flat elastomeric gasket or conventional O-ring may also be arranged between the surface and the outer surface of the wall to provide a seal against any adverse environmental conditions. The receptacle housing 22 is secured to the wall using an internally threaded coupling nut (not shown) that is threaded into an externally threaded surface provided on the receptacle housing 22. As the coupling nut is tightened, the receptacle housing 22 is pulled toward the outer surface of the wall, thereby compressing the joint and providing an effective seal.

[0037] The fiber optic receptacle 20 further includes a retainer 46 that is secured to the receptacle housing 22 adjacent to the inner end of the housing 22. The retainer 46 may be secured to the receptacle housing 22 in any suitable manner. In the embodiments shown, retainer 46 defines a plurality of retaining clips that fit into corresponding slots defined by receptacle housing 22. As such, retainer 46 is securely retained within receptacle housing 22. Retainer 46 secures the assembly of alignment 30 within the receptacle housing 22 as the retainer retaining clips fit into the slots of the receptacle housing 22.

[0038] By inserting the alignment assembly 30 from the inner end, or rear, of the receptacle housing 22 and retaining it in place with the retainer 46, the alignment assembly 30 may be removed only from the inner or rear portion of the container. 20. In embodiments in which the receptacle 20 is secured within a wall of a containment, the alignment assembly 30 can only be accessed from the inside or rear of the receptacle 20. In contrast, conventional receptacles include an external two-pronged design. parts that allow the alignment assembly 30 to be removed from the outside or front of the receptacle 20. In such a design, a field technician is able to remove the alignment assembly 30 by removing a second external piece from the receptacle housing 22 to gain access to the alignment assembly 30 from outside the containment without the need to enter the containment. Multi-piece designs may also require a seal between the first piece and the second piece of the receptacle housing 22 to prevent water ingress. In the present embodiments, the design eliminates the need for an internal seal. Additionally, the freeze/thaw cycle will not cause the second part to move away or separate from the first and expose the optical fibers inside the containment and rear ferrule to adverse environmental conditions such as water ingress and dust, dirt and insect intrusion.

[0039] As shown particularly in Figures 2 and 3, the retainer 46 engages the receptacle housing 22 so as to retain the alignment assembly 30 within the receptacle housing 22. The retainer 46 defines an opening large enough to allow the ferrule from the rear (not shown) that is mounted on the ends of the optical fibers originating from within the housing pass through the retainer 46 into the alignment assembly 30. At the same time, the opening is small enough to not allow the alignment assembly 30 be removed without removing retainer 46 from receptacle housing 22. Once assembled, retainer 46 must be removed from receptacle housing 22 to access alignment assembly 30 or to access the rear ferrule (not shown), such as for cleaning , replacement or similar. In an alternative embodiment, the retainer 46 may comprise threads that engage corresponding threads in the receptacle housing 22 to retain, access, and remove the alignment assembly 30 from the receptacle housing 22. Since the alignment assembly 30 or the ferrule rear has been cleaned, repaired or replaced, the alignment assembly 30 is inserted into the internal cavity 24 defined by the receptacle housing 22 and the retainer 46 is secured to the receptacle housing 22.

[0040] The fiber optic receptacle 20 may further include at least one biasing member disposed within the receptacle housing 22. In the embodiments shown, the biasing member comprises a pair of linear helical springs 56, preferably having a spring constant low (k), which operatively engages the alignment assembly 30 to urge the alignment assembly 30 toward the outer end of the receptacle housing 22 so that the alignment assembly 30 is spring loaded. However, at least one biasing member may be any component, structure or material that biases the alignment assembly 30 toward the outer end of the receptacle housing 22. Springs 56 are positioned between brackets 34, 40 adjacent the first end. of the alignment assembly 30 and the retainer 46 and are supported by posts, as shown and described in greater detail below. In addition to spring loading the alignment assembly 30, the plug ferrule of the fiber optic plug that is inserted into the alignment assembly 30 through the outer end of the receptacle housing 22 is also typically spring loaded. Thus, spring loading of the alignment assembly 30 and plug ferrule urges the end face of the plug ferrule against the end face of the rear ferrule within the alignment assembly 30. Unlike conventional alignment assemblies, connector sleeves or adapter sleeves for mating ferrules, the alignment assembly 30 need not include latches to mechanically engage the plug ferrule, since spring loading will deflect the alignment assembly 30 into engagement with the plug ferrule within the housing receptacle 22 However, the second end of the alignment assembly 30 preferably includes a means for engaging the rear ferrule, such as, for example, a locking mechanism that includes one or more latches. Thus, an alignment assembly 30 is also provided in accordance with an embodiment that may also be used in situations not involving a fiber optic receptacle 20. In alternative embodiments, the fiber optic receptacle 20 may include other types of polarization members. , in addition to or instead of one or more springs 56.

[0041] With reference to Figures 3 and 4, a cross-sectional view of the assembled fiber optic receptacle of Figure 2 is shown in Figure 3 and a cross-sectional view of the assembled fiber optic receptacle of Figure 2. The outer end of the receptacle housing 22 is internally threaded so as to threadably engage an externally threaded fiber optic plug (not shown). In preferred embodiments, the alignment assembly 30 is received through the inner end of the receptacle housing 22 and is retained within the internal cavity 24 by retainer 46. The alignment assembly 30 may be shaped and designed to accommodate and match a variety of different types of fiber optic connectors mounted on the end of a fiber optic cable. As shown, the alignment assembly 30 defines a pass-through opening that extends longitudinally through the opposite first end and the second end for receiving and aligning the ferrules of the fiber optic connectors. A first fiber optic connector (not shown) including a plug ferrule is inserted into the first end of the alignment assembly 30. A second fiber optic connector (not shown) including a rear ferrule which is mounted to the ends of one or more fibers optics originating from within the containment is inserted through the opening defined by the second end of the alignment assembly 30. The alignment assembly 30 preferably defines an alignment groove 31 for receiving a retaining clip (not shown) of the second optical fiber connector. . The slot 31 is also configured as a coding feature used to align the second optical fiber connector within the alignment assembly 30 and the retaining clip is used to connect/disconnect the second optical fiber connector. The alignment assembly 30 may further include an internal chamfer for guiding the second fiber optic connector into the alignment assembly 30. The chamfer may help protect the ferrule end face of the second fiber optic connector by guiding the connector housing during insertion. in alignment set 30.

[0042] Referring particularly to Figure 3, in embodiments of the fiber optic receptacle 20 in which the polarizing member includes one or more springs 56, the retainer 46 includes one or more tapered posts 62 that extend in the lengthwise direction of the retainer 46 toward the inner end of the receptacle housing 22. The tapered posts 62 serve as support structures for the springs 56. The retainer 46 includes the same number of posts 62 as the number of springs 56 so that each spring can be mounted on a respective pole. Furthermore, each spring 56 is preferably longer than the respective post 62, even in the compressed state of the spring. As such, the posts 62 serve to position the springs 56 which in turn press the alignment assembly 30 and, more particularly, the spring posts 64 of the supports 52 of the alignment assembly 30. The spring posts 64 of the supports 52 are aligned with the posts 62 of the retainer 46. Thus, each spring 56 contacts a respective bias member support 52 of the alignment assembly 30 and urges the alignment assembly 30 toward the outer end of the receptacle housing 22 The spring posts 64 of the supports 52 are preferably tapered and, more preferably, conical in shape. Both sets of posts 62, 64 are preferably tapered to capture the springs 56 during assembly, thereby facilitating loading and positioning of the springs 56 between the alignment assembly 30 and the retainer 46. In other words, the tapered shape provides a mechanism supply to properly seat the springs 56. As the springs 56 have a low spring constant (k), they are subject to bending and even buckling during assembly. Thus, improper spring seating can result in poor or uneven biasing of the alignment assembly 30. The tapered shape of the posts 62, 64 provides adequate seating of the spring 56 and eliminates assembly errors.

[0043] With reference to Figures 5 and 6, a front perspective view of the retainer 46 of the fiber optic receptacle 20 of Figure 1 is shown in Figure 5 and a rear perspective view of the retainer 46 of the fiber optic receptacle 20 of Figure 1 is shown in Figure 6. The opening 50 through retainer 46 is sized to accommodate the second end of the alignment assembly 30 so that an optical connector and/or ferrule can be inserted through the opening 50 in the alignment assembly 30. retainer 46 may be sized and shaped in any suitable manner. In the embodiments shown herein, the retainer 46 includes a cylindrical portion of substantially similar diameter to the inner end of the receptacle housing 22, therefore it appears that the retainer 46 extends the length of the receptacle 20. As shown in Figure 6, the side rear of retainer 46 defines a generally flat surface.

[0044] Retainer 46 is secured to receptacle housing 22 at the inner end of housing 22. Retainer 46 may be secured to housing 22 in various ways, but in the embodiments shown, retainer 46 defines a pair of retaining clips that are received by the slots 48 defined by the receptacle housing 22. As such, the retainer 46 and the receptacle housing 22 of this embodiment are firmly engaged. The alignment assembly 30 can only be removed from the inside of the receptacle 20 in embodiments in which the receptacle is positioned within a wall of a containment. Retainer 46 is removed from receptacle housing 22 to access alignment assembly 30 or to access the rear ferrule (not shown). In an alternative embodiment, the retainer 46 may be threaded and removed from the receptacle housing 22.

[0045] In the embodiment shown, the retainer 46 includes a pair of tapered posts 62 that serve as supports for the springs 56 so that each spring 56 is mounted on a respective post 62. The posts 62 are seated within the recesses defined by the retainer. 46. The recesses are an additional means for retaining the springs 56 during assembly and use of the receptacle. As stated above, the posts 62 are tapered so as to capture the springs 56 during assembly, thus facilitating loading of the springs 56. The retainer 46 further defines a plurality of tenons 68 formed adjacent to the opening 50 of the retainer 46. Four tenons 68 are shown, wherein each tang 68 is positioned medially on one of the four side walls defining the opening 50. The tangs 68 are operable to guide the alignment assembly 30 to properly align with the first (i.e., plug) fiber connector. optics and the second (i.e. receptacle) fiber optic connector. The tenons 68 are sized to allow the alignment assembly 30 to rotate slightly within the opening 50. In other words, the tenons 68 allow slight angular rotation without allowing axial movement of the alignment assembly 30, thus allowing the angles at a pair of opposing angular physical contact (APC) ferrules align properly. The tenons 68, together with the chamfer of the alignment assembly 30, adequately provide alignment of opposing APC ferrules.

[0046] A fiber optic plug of a fiber optic drop cable can be shown engaged with a fiber optic receptacle 20. At the same time, the drop cable associated with the plug is strain relieved in the receptacle 20. When a plug is not yet has engaged the receptacle 20, the receptacle is preferably covered with some form or operable dust cover (not shown) to prevent water and contaminants, such as dust, dirt and insects, from reaching the internal cavity 24 of the container 20. When removed, the dust cap can be retained in receptacle 20 using a cord and reused if the plug is later disengaged from receptacle 20. A dust cap can also be used to protect the optical connector mounted on the drop cable prior to installation until the plug is seated in receptacle 20. Although a containment wall is not shown, a threaded coupling nut can be used to secure the receptacle 20 within an opening in the containment wall. An elastomeric gasket may be disposed between the coupling nut and the flat surface defined by the flanged portion 26 of the receptacle housing 22. The housing wall is preferably disposed between the gasket and the coupling nut so that the gasket is compressed against the wall as the coupling nut is tightened. The gasket is provided to prevent water and contaminants from penetrating through the opening in the containment wall. In alternative embodiments, a protective cover may be disposed on the inside of the receptacle 20 to allow the assembly to be installed in a breathable confinement and may be rendered obsolete if the receptacle is reliably sealed from the environment.

[0047] Referring again to Figures 1 and 2, the outer periphery of the receptacle housing 22 is configured to define an alignment mark for the keyed alignment of the fiber optic plug with the receptacle 20. The plug and corresponding receptacle 20 are configured to allow coupling in only one orientation. In preferred embodiments, this orientation may also be marked on the plug using alignment marks so that a less qualified field technician can easily fit the plug with the receptacle. Any suitable clue can be used. After alignment, the field technician engages the outer threads of the plug with the inner threads of the receptacle 20 to secure the plug to the receptacle 20. In an alternative embodiment, the plug may define internal threads and the receptacle housing 22 may define external threads. . Additionally, any type of cooperative coupling means, such as bayonet, push-fit, or press-fit, may be used.

[0048] The receptacle housing 22 of the fiber optic receptacle 20 is preferably configured for mounting on a wall of an enclosure, retains the alignment assembly 30, and aligns the ferrule of the plug with the ferrule of the rear so that they meet. fit in only one preferred orientation. This feature is especially advantageous for optical connections utilizing APC-type ferrules, where minimal angular displacement is required, as well as multi-fiber ferrules that are often not centered. Furthermore, the optical connection can be easily connected or disconnected by simply coupling or uncoupling a fiber optic plug with the receptacle 20 as previously described.

[0049] The foregoing is a description of various embodiments that are given herein by way of example only. Although the one-piece fiber optic receptacle has been described with reference to preferred embodiments and examples thereof, other embodiments and examples may perform similar functions and/or achieve similar results. All such embodiments and equivalent examples are within the spirit and scope of the disclosure and are intended to be covered by the appended claims.

Claims (10)

Fiber optic receptacle characterized by the fact that it comprises:
a receptacle housing defining an internal cavity opening through an internal end and an opposing external end;
an alignment assembly disposed within the internal cavity defined by the receptacle housing and received through the internal end, wherein the alignment assembly comprises a plurality of alignment brackets and an alignment sleeve having ends contained within each alignment bracket; It is
a retainer for retaining the alignment assembly within the internal cavity defined by the receptacle housing, wherein the retainer has an opening and a plurality of tenons disposed around the opening. Fiber optic receptacle according to claim 1, further comprising at least one polarizing member disposed within the receptacle housing that operatively engages with at least one of the retainer and the alignment assembly so as to impel the alignment assembly toward the outer end of the receptacle housing. Optical fiber receptacle according to claim 2, characterized in that at least one polarization member comprises a linear spring. Fiber optic receptacle according to claim 2, further comprising at least one polarization member support provided on at least one of the retainer and alignment assembly for operatively supporting at least one polarization member within of the receptacle housing. Fiber optic receptacle according to claim 4, wherein the at least one polarization member support comprises at least one tapered post that retains and guides a corresponding polarization member during assembly of the fiber optic receptacle. The fiber optic receptacle of claim 1, wherein the retainer is removable and wherein the alignment assembly is inserted into and removed from the internal cavity through the inner end of the receptacle housing when the retainer is removed from the housing. of receptacle. Fiber optic receptacle according to claim 1, wherein the retainer allows angular rotation of the alignment assembly while preventing axial movement of the alignment assembly. Fiber optic receptacle according to claim 1, wherein the fiber optic receptacle is configured for positioning in an opening in a wall of a confinement. Fiber optic receptacle according to claim 1, wherein each alignment bracket prevents the alignment assembly from being incorrectly loaded into the receptacle housing. The fiber optic receptacle of claim 1, wherein each alignment bracket extends so that it rests within guide channels defined within the internal cavity of the receptacle housing.

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