A subassembly for incorporation within a communications connector jack includes a contact support member and a pair of electrical contacts mounted with respect thereto in side-by-side relation. The contact support member includes a proximal end portion and a body portion extending therefrom. The proximal end portion defines a planar rear face allowing the contact support member to be securely mounted in a cantilever fashion with respect to a corresponding planar mounting surface of a printed circuit board (PCB). An upper region of the body portion defines a sufficiently small profile as viewed along the longitudinal direction of extension of the contact support member from in front of its distal end to permit the incorporation of multiple respective instances of the contact support member within a common connector jack housing to define a desired contact layout geometry for interaction with a cooperative plug member.
Mark E. Martich
Original Assignee: Ortronics, Inc.
Classification: Basic Electric Elements
CROSS-REFERENCE TO RELATED APPLICATIONS
This application is a continuation of co-pending U.S. non-provisional application Ser. No. 11/800,587, entitled “CONNECTOR ASSEMBLY FOR USE WITH PLUGS AND PRETERMINATED CABLES”, filed May 7, 2007.
1. Technical Field
The present disclosure is directed to connector assemblies for use with electrical wires/cables that include a plug member, particularly preterminated wires/cables. The present disclosure is further directed to connector assemblies and associated plugs that are adapted for delivery of “Category 6A” level performance in an unshielded twisted pair (UTP) environment.
2. Background Art
With the continued evolution of data communication applications, performance standards and requirements continue to advance. The structured cabling industry has experienced a progression from Category 3 level performance standards/requirements, through Category 5/5E, Category 6, and more recently Category 6A performance standards/requirements. At each stage, manufacturers of cabling and connector technologies have been required to address data communication capabilities and limitations of their existing product offerings. Of primary importance in meeting industry requirements is the control/minimization of noise/cross-talk encountered in the connector assemblies. Noise/cross-talk issues become more pronounced as data communication frequencies are increased.
Typical connector assemblies include a jack and a plug that are adapted to detachably engage to effect a data communication connection. Typical RJ-45 connector assemblies include a jack and a plug, each of which includes eight conductors in a predefined side-by-side orientation. Various techniques have been developed to control/address noise and crosstalk that are generated in the jack/plug interface, including capacitive compensation in the jack and/or plug. Noise/crosstalk compensation may be introduced through physical arrangements of the conductors within the jack and/or plug, as well as compensation introduced on printed circuit boards associated with the jack and/or plug.
Alternative conductor layouts for purposes of jack/plug combinations have been proposed. For example, U.S. Pat. No. 6,162,077 to Laes et al. and U.S. Pat. No. 6,193,533 to De Win et al. disclose male/female connector designs wherein shielded wire pairs are arranged with a plurality of side-by-side contacts and additional contact pairs positioned at respective corners of the male/female connector housings. The foregoing arrangement of contacts/contact pairs for shielded cables is embodied in an International Standard—IEC 60603-7-7—the contents of which are hereby incorporated herein by reference. The noted IEC standard applies to high speed communication applications with 8 position, pairs in metal foil (PIMF) shielded, free and fixed connectors, for data transmissions with frequencies up to 600 MHz.
In completing cabling installations, it is generally necessary to feed wiring/cabling from location-to-location, e.g., through conduits and/or in open spaces behind walls, above ceilings and below floors. Frequently, the wire/cable is fed from spools, introduced through the back/side of a wiring box, and terminated by an installation professional, e.g., by punching down individual wires with respect to insulation displacement connectors (IDCs) or the like. According to this conventional installation technique, the installer is able to define the length of each wiring/cabling run at the time of installation, thereby maintaining flexibility. However, the termination process is time-consuming and it is necessary to test/confirm system performance after the installation is complete.
As an alternative installation technique, preterminated wires/cables may be employed to achieve point-to-point wiring connectivity. A preterminated wire/cable generally includes a plug that is pre-mounted with respect to at least one end of a predetermined length of wire/cable. The plug is generally mounted with respect to the wire/cable by the manufacturer and, as part of the manufacturer's quality control procedures, performance at the interface between the wire/cable and the pre-mounted plug is verified before shipment to the installation site. Devices have been developed to encase and protect the pre-mounted plug during the installation process, e.g., as the plug is fed from point-to-point by the installation team. In this way, the potential for damage to the wire/plug connections and associated data communication performance is minimized.
For installations that employ preterminated wires/cables, the necessary wire/cable lengths, types and colors are generally determined before the requisite wiring/cabling is ordered from a manufacturer. Once the length calculations are made, an order is generated specifying the wires/cables that are required for a specific installation (with appropriate margins for error/flexibility), and the manufacturer preassembles terminated cables as specified. The terminated ends, i.e., the pre-mounted plugs, are generally fed into a wiring box and connected to a rearwardly facing jack positioned therewithin to complete a wiring connection. The foregoing jack may be part of a jack assembly that includes oppositely directed jack units, each adapted to receive a plug therewithin. Thus, the rearwardly directed jack generally receives the preassembled plug associated with a preterminated wire/cable, and the forwardly (or outwardly) directed jack generally receives a plug associated with an end user application, e.g., a computer, printer or the like.
Despite efforts to date, a need remains for connector assemblies and techniques that provide enhanced flexibility and/or performance for preterminated wiring/cabling applications. A need also remains for connector assemblies and techniques that facilitate interaction between plugs that feature different contact layouts/alignments. Still further, a need remains for connector assemblies and techniques that facilitate enhanced data communication performance in an environment that includes, in whole or in part, unshielded twisted pair (UTP) wires/cables. These and other needs are satisfied by the connector assemblies and techniques disclosed herein.
The present disclosure is directed to connector assemblies and techniques for use in preterminated wiring/cabling applications. The disclosed connector assemblies and techniques facilitate interaction between plugs that feature different contact layouts/alignments, e.g., a first plug that features a conventional 8-position RJ-45 contact layout and a second plug that features a contact layout according to the IEC 60603-7-7. The disclosed connector assemblies and techniques support enhanced data communication performance by facilitating interconnection between plugs designed/fabricated according to different contact layout geometries. Stated differently, the disclosed connector assemblies provide compatibility between cabling infrastructure/plugs that feature a conventional RJ-45 contact geometry, and next generation cabling infrastructure/plugs that feature a contact layout according to the IEC 60603-7-7 standard. In this way, optimal data communication performance may be achieved, while maintaining interoperability with the existing RJ-45 cable/plug environment.
The present disclosure is also directed to cable/plug combinations wherein the cable features fully shielded twisted pair (FTP), shielded twisted pair (STP), or unshielded twisted pair (UTP) wires. The cable/plug assembly includes a plug body wherein individual wires are brought into electrical communication with electrical contacts that are exposed relative to the exterior of the plug body. The electrical contacts are positioned in quadrants of the plug body, when viewed in cross-section, such that the plug complies with the contact geometry set forth in the IEC 60603-7-7 standard. The cable/plug assembly is generally a preterminated assembly, whereby the plug is pre-mounted to the cable before shipment to an installation location or distribution channel. A pulling eye assembly may be provided that defines a cavity sized and configured to receive the plug body and a portion of the cable. The pulling eye assembly may include a hinged cover that encases the plug body for pulling of the cable/plug assembly from point-to-point, e.g., through a conduit or an open space in a wall, floor or ceiling.
The disclosed preterminated FTP/STP/UTP cable and plug assembly with IEC 60603-7-7 contact geometry is advantageously adapted to engage and electrically communicate with a jack assembly. The jack assembly may be associated with a connector that includes a pair of jack assemblies, e.g., oppositely directed jacks, whereby cable installation is expedited and facilitated. In exemplary embodiments, the preterminated cable and plug assembly features UTP wires and, in such implementations, the grounding associated with shielded cabling solutions is unnecessary. Thus, the jack assembly (or the connector that includes the jack assembly) for receiving and cooperating with the preterminated UTP cable/plug assembly need not include grounding features as are known in the art for shielded applications.
Additional features, functions and benefits of the disclosed connectors, cable/plug assemblies and techniques will be apparent from the detailed description which follows, particularly when read in conjunction with the appended figures.
BRIEF DESCRIPTION OF FIGURES
To assist those of skill in the art in making and using the disclosed connectors and plug/cable assemblies, reference is made to the accompanying figures, wherein:
FIG. 1 is a perspective side view of an exemplary connector according to the present disclosure;
FIG. 2 is an exploded perspective view of an alternative exemplary connector according to the present disclosure;
FIG. 3 is an exploded perspective view of a further alternative exemplary connector according to the present disclosure;
FIG. 4 is a front view of an exemplary connector according to the present disclosure;
FIG. 5 is a cross-sectional view of the exemplary connector of FIG. 4, taken along line A-A therein;
FIG. 6 is a perspective side view of a plug/cable assembly positioned within a pulling eye assembly according to an exemplary embodiment of the present disclosure;
FIG. 7 is a perspective side view of the plug/cable assembly of FIG. 6 with the pulling eye assembly rotated into its closed position;
FIG. 8 is a perspective side view of an exemplary contact pair subassembly according to the present disclosure;
FIG. 9 is an exploded perspective view of the contact pair subassembly of FIG. 8;
FIG. 10 is an exploded patch panel assembly that includes six (6) connectors according to the present disclosure; and
FIG. 11 is a front schematic view of a contact alignment for an exemplary jack according to the present disclosure.
DESCRIPTION OF EXEMPLARY EMBODIMENT(S)
Connector assemblies and cabling/wiring techniques are disclosed herein. The disclosed connector assemblies/techniques have particular utility in preterminated wiring/cabling applications, but the disclosure is not limited to such applications and/or implementations. In exemplary embodiments, connector assemblies—including patch panel assemblies that include a plurality of individual connector assemblies—facilitate interaction between plugs that feature different contact layouts/alignments. Thus, in an exemplary implementation, the connector defines a first jack that is configured and dimensioned to electrically cooperate with a first plug featuring a conventional RJ-45 contact layout, and a second jack that is configured and dimensioned to electrically cooperate with a second plug featuring a contact layout consistent with the IEC 60603-7-7 standard.
The disclosed connector assemblies and techniques support enhanced data communication performance by facilitating interconnection between plugs designed/fabricated according to different contact layout geometries. Stated differently, the disclosed connector assemblies provide compatibility between cabling infrastructure/plugs that feature a conventional RJ-45 contact geometry, and next generation cabling infrastructure/plugs that feature a contact layout according to the IEC 60603-7-7 standard. In this way, optimal data communication performance may be achieved, while maintaining interoperability with the existing RJ-45 cable/plug environment. Of note, the disclosed connector assemblies/techniques may be employed to connect FTP/STP cables with UTP cables, FTP/STP cables with FTP/STP cables, or UTP cables with UTP cables. Based on the cabling to be joined to the jacks associated with the disclosed connector assembly, shielding and/or grounding is provided as necessary.
With reference to FIGS. 1-5, connector assemblies 10, 100 and 500 are schematically depicted. Connector assemblies 10, 100 and 500 are structurally and electrically equivalent, except that different latching mechanisms are provided for joining housing elements together, as described in greater detail below. With initial reference to FIG. 1, fully assembled connector assembly 10 includes first housing 12 and second housing 14 that are adapted to latch relative to each other so as to define a unified connector housing unit. In the exemplary embodiment of FIG. 1, first and second deflectable latching members 18, 20 extend from the top surface of first housing 12. Such deflectable latching members 18, 20 detachably engage cooperate slots formed in second housing 14 so as to join first and second housings. Additional latching structures (not shown) may be provided on first and second housings 12, 14, e.g., along bottom surfaces thereof, to further facilitate mounting therebetween. Second housing 14 defines an upstanding ridge 16 that facilitates mounting/positioning of connector assembly 10 relative to a structure or surface, e.g., a wiring box, patch panel or the like.
First housing 12 defines a first jack opening 20 on a face 22 thereof. A label slot 23 is defined above jack opening 20 on face 22. Label slot 23 permits an installer to label the electrical connection associated with connector 10 for future reference. Alternative labeling techniques may be employed, as are known in the art. A second jack opening (not pictured) is formed on a face 24 of second housing 14.
First housing 12 and second housing 14 are typically fabricated from a plastic material, e.g., polycarbonate. Grounding of the first housing 12 and second housing 14 is generally not required because the plug/cable combinations that are mounted to connector 10 feature unshielded twisted pair (UTP) wires. Despite the omission/elimination of shielding from connector assembly 10, advantageous performance levels are achieved through the positioning of contacts/conductors, particularly with respect to the IEC 60603-7-7 contact geometry, and the inclusion of compensation technology, particularly for the conventional RJ-45 contact geometry, as is known in the art.
Turning to FIG. 2, an alternative connector assembly 100 is schematically depicted in an exploded manner. Connector assembly 100 includes first housing 102, second housing 104 and contact subassembly 106. First housing 102 defines a first jack opening 108 in a first face 110 thereof. Contact support members 112, 114, 116 and 118 extend from contact subassembly 106 and define, in part, outer boundaries of jack opening 108. A jack opening (not pictured) in face 120 of second housing 104. A contact insert 122 extends into a rear opening 124 formed in second housing 104 and defines, in part, a boundary of the jack opening formed in second housing 104. A printed circuit board (PCB) 126 is positioned between contact insert 122 and contact support members 112, 114, 116 and 118. PCB 126 includes conventional electronic elements, e.g., traces printed or etched on a non-conductive substrate that facilitate electrical connection across connector 100.
With reference to FIGS. 2, 8 and 9, each of contact support members 112, 114, 116 and 118 include two contacts in side-by-side relation. Thus, with particular reference to FIGS. 8 and 9, contact support member 112 is depicted in greater detail. It is to be understood that each of contact support members 112, 114, 116 and 118 may be advantageously configured in like manner, thereby facilitating efficient and cost effective manufacture and inventory practices. Contact support member 112 includes a contact support body 130 and an end cap 132 that support electrical contacts 134, 136 in a side-by-side orientation. Contact members 134, 136 are of substantially identical geometry and include a distal foot 138, an intermediate contact region 140 and a proximal PCB-mounting feature 142. Contact support body 130 defines side-by-side channels 144, 146 that are adapted to receive the distal portion of electrical contacts 134, 136 and support distal foot 138, thereby ensuring that contact region 140 firmly engages a corresponding plug contact when the plug is inserted into jack opening 108 of first housing 102. Thus, each of electrical contacts 134, 136 is deflectable when engaged by a plug, but remains upstanding so as to make effective and reliable electrical contact therewith.
Contact support body 130 further defines an abutment surface 148 that is adapted to cooperate with a cooperating abutment face (not numbered) on end cap 132 to capture electrical contacts 134, 136 therebetween. A ramp 150 is defined on contact support body 130 to support electrical contacts 134, 136 in the region between contact region 140 and PCB-mounting feature 142. End cap 132 defines first and second deflectable latch extensions 152, 154 that facilitate mounting of end cap 132 relative to contact support body 130. End cap 132 also includes a downward extension 156 that is dimensioned for receipt in an aperture 157 formed in contact support body 130 and that functions to space/isolate electrical contacts 134, 136 from each other, thereby ensuring appropriate electrical operation thereof.
Contact support body 130 also generally includes various structural features that facilitate mounting of contact support body with respect to first housing 102. Thus, for example, first and second alignment channels 158, 160 may be provided in a front face of 162 of contact support body 130 for interaction with corresponding features molded onto the inner surface of first housing 102. Similarly, ribs 164, 166 molded on side face 168 of contact support body 130. Ribs 164, 166 may function to space/position contact support body 130 relative to adjacent structures within first housing 102. Additional structural features may incorporated into or onto contact support body 130 (as well as first housing 102) to facilitate relative positioning therebetween, as will be readily apparent to persons skilled in the art. Thus, the present disclosure is not limited to or by the exemplary positioning features/elements disclosed herein, but extends to and encompasses alternative positioning features/elements as would be readily apparent to persons skilled in the art.
Returning to FIG. 2, contact support members 112, 114, 116 and 118 are mounted with respect to PCB 126 through interaction between PCB-mounting features 142 formed at the proximal end of electrical contacts 142, and corresponding mounting apertures/through holes formed on PCB 126. Thus, in the exemplary embodiment of FIGS. 8 and 9, PCB-mounting feature 142 includes a deflectable eyelet that is adapted to be inserted into a corresponding aperture/through hole formed in PCB 126 to secure the electrical contact with respect to PCB 126. Securement therebetween may be further ensured through a welding, soldering, or other conductively adhesive operation, as is known to persons skilled in the art. Additional mounting features and/or structures may be associated with end cap 132 and/or PCB 126 to further enhance the mounting interaction therebetween, e.g., an adhesive, as will be readily apparent to persons skilled in the art.
Contact support members 112, 114, 116 and 118 extend in a substantially cantilever fashion from PCB 126 and are spaced relative to each other so as to define a desired contact geometry for interaction with a cooperative plug member. With reference to FIG. 11, the contact alignment within exemplary jack opening 108 is schematically depicted. Thus, the pair of electrical contacts associated with contact support member 112 correspond to wire pair 1/2, the pair of electrical contacts associated with contact support member 114 correspond to wire pair 7/8, the pair of electrical contacts associated with contact support member 116 correspond to wire pair 4/5, and the pair of electrical contacts associated with contact support member 118 correspond to wire pair 3/6. Due to the pairing and spacing of electrical contacts within jack housing 108 (and the corresponding contact pairing and spacing of the jack to be inserted therein), crosstalk/noise is substantially reduced or eliminated with respect to the interaction between electrical contacts associated with contact support members 112, 114, 116 and 118, and the corresponding contacts associated with a plug to be inserted therein.
Turning to FIGS. 6 and 7, an exemplary cable/plug assembly 300 for use in combination with jack opening 108 of connector assembly 100 is schematically depicted. Cable/plug assembly 300 includes a cable 302 and a plug 304 fixedly mounted with respect thereto. As depicted in FIGS. 6 and 7, cable/plug assembly 300 constitutes a preterminated assembly, i.e., an cable/plug assembly that is constructed by a manufacturer prior to shipment to an installation site and/or distribution channel. The length of cable 302 is generally defined for a particular installation based on the installer's determination of the requisite cable run. For example, the installer may determine that a plug/cable assembly of 100′ length is required to extend from point A to point B. The installer would communicate this need to a manufacturer of preterminated plug/cable assemblies (generally, as part of a larger order that includes a plurality of plug/cable assembly requirements of differing cable lengths), who would fabricate the plug/cable assembly to the installer's specification(s).
At the installation site, plug 304 associated with plug/cable assembly 300 is advantageously delivered to a desired location through a conduit and/or through open space behind a wall, below a floor or above a ceiling. To facilitate such delivery, a removable delivery structure 400 may be provided to protect the plug/cable interface during the cable installation process. Exemplary delivery structure 400 takes the form of a pulling eye assembly that includes a base 402 and a hinged cover 404. The base 402 and cover 404 together define a cavity 406 that is dimensioned and configured to receive plug 304 and a portion of cable 302. Substantially semi-circular openings 408, 410 are defined in rear faces 412, 414 of base 402 and cover 404, respectively. The semi-circular openings 408, 410 cooperate to define a substantially circular opening that is dimensioned to receive and surround cable 302. A pair of spaced, deflectable latch members 416, 418 are defined on hinged cover 404 for detachable engagement with latching slots 420, 422 formed with respect to base 402.
To facilitate delivery of plug/cable assembly 300 to a desired location, base 402 further defines a substantially pyramidal front extension 430 that defines a pulling eye 432 at a front face thereof. The inclined surfaces of pyramidal front extension 430 facilitate routing of plug/cable assembly 300 to a desired location. Similarly, pulling eye 432 is configured and dimensioned to cooperate with a detachable pulling member, e.g., a cable, wire or the like, that may be used to pull plug/cable assembly 300 and delivery structure 400 to a desired location. By limiting the pulling force associated with routing of plug/cable assembly 300 to delivery structure 400, potential damage to the interface between plug 304 and cable 302 is minimized and/or eliminated. Once the plug/cable assembly 300 reaches a desired location, latch members 416, 418 are detached from the cooperative latching slots 420, 422 and hinged cover 404 is rotated/pivoted to its open position (e.g., the position shown in FIG. 6). The plug/cable assembly 300 is then removed from delivery structure 400 and the delivery structure discarded or retained for potential reuse.
With further reference to FIG. 6, it is noted that plug 304 includes two pairs of exposed contacts on an upper face thereof. As is apparent from the exemplary contact geometry depicted in FIG. 11, contact pair 322 may correspond to wire pair 1/2 or wire pair 4/5, while contact pair 320 may correspond to wire pair 7/8 or wire pair 3/6, depending on which face of plug 304 is upwardly directed in delivery structure 400. When inserted within jack opening 108 of connector assembly 100, contact pairs 320, 322 make electrical contact with corresponding contact pairs on contact support members 112, 114, or contact support members 116, 118. Additional contact pairs (not visible) are positioned on the opposite side of plug 300 and are adapted to engage corresponding contacts associated with contact support members 112, 114 or contact support members 116, 118, as the case may be.
Of particular note, the plug/cable assembly 300 of the present disclosure is advantageously formed with respect to a cable 302 that includes unshielded twisted pair (UTP) wires. Thus, within plug 304, UTP wires are brought into electrical contact with appropriate contact pairs defined by plug 304. UTP wire pairs 1/2 are advantageously brought into electrical contact with contacts 322, while wire pairs 7/8 are advantageously brought into electrical contact with contacts 320. Similar electrical connections are achieved with respect to the other UTP wires and contacts associated with plug 304. Inasmuch as cables that feature UTP wiring are employed according to the present disclosure, shielding issues associated with the plug/jack interface are eliminated.
Returning to FIG. 2, connector assembly 100 includes a latching slot 170 defined in first housing 102 that is adapted to engage upstanding latch 172 defined on second housing 104. Additional latching structures, e.g., latch members 174, may be provided to ensure secure mounting of first and second housings 102, 104 and/or mounting of connector assembly 100 relative to ancillary housings and/or support structures (not pictured).
When fully assembled, connector assembly 100 defines oppositely directed first and second jack openings. Thus, with reference to FIGS. 4 and 5, first jack opening 108 and second jack opening 180 are oppositely directed with respect to the longitudinal axis of the connector assembly 100. Contacts 184 extend from contact insert 122 into second jack opening 180 are adapted to interact with a conventional RJ-45 plug. Thus, contacts 184 are in side-by-side orientation, as is well known to persons skilled in the art. To address noise/crosstalk associated with the interaction of contacts 184 and a conventional RJ-45 plug, PCB 126 generally includes compensation functionality that is designed to offset/compensate for such noise/crosstalk. The design and operation of PCB-based compensation, particularly in an RJ-45 environment, is well known to persons skilled in the art. Of note, connector assembly 100 may include a labeling position 182 on a face 110 of first housing 102, such labeling position 182 permitting an installer to label the connection port associated with connector assembly 100.
In use and with particular reference to the cross-sectional view of FIG. 5, connector assembly 100 is effective to provide an electrical connection between a first plug/cable that includes contacts geometrically arranged according to the IEC 60603-7-7 standard, i.e., by inserting such first plug in first jack opening 108, and a second plug/cable that includes contacts geometrically arranged according to a conventional RJ-45 contact alignment, i.e., by inserting such second plug in second jack 180. The first plug/cable are advantageously preterminated by the manufacturer and preferably feature UTP wiring (although the present disclosure may also be employed with FTP/STP wiring), thereby permitting an installer to feed the preterminated first plug (e.g., exemplary plug 304 of FIG. 6) into first jack opening 108 at an installation site. Indeed, in a preferred implementation of the present disclosure, connector 100 is positioned in a wiring box (e.g., in conjunction with appropriate housing structure(s)), and the preterminated plug 304 is introduced to jack opening 108 within such wiring box (e.g., a single gang box) as part of the installation process and without the need to punch down wires, test wiring performance, etc.
A second plug (not pictured) may be inserted into second jack opening, e.g., by an end-user, to complete an electrical circuit. Thus, the second jack opening may receive an RJ-45 plug associated with a computer, laptop, printer or other component. Compensation is introduced to such electrical circuit, e.g., by PCB 126, to compensate for the noise/crosstalk associated with the RJ-45 connection afforded by second jack opening 180.
Connector 100 offers superior electrical performance, accommodates the in situ combination of RJ-45 and IEC 60603-7-7 technologies, and facilitates the use/implementation of preterminated jack assemblies, e.g., in a FTP/STP and/or UTP environment. Compensation is provided, as necessary, to address noise/crosstalk associated with the RJ-45 aspect of the connector assembly, while compensation is unnecessary with respect to the IEC 60603-7-7 aspect of the connector assembly. Similarly, the implementation and use of UTP wiring obviates the need for shielding structures and/or functionalities with respect to the IEC 60603-7-7 aspect of the connector assembly.
Turning to FIG. 3, an alternative connector assembly 500 is schematically depicted according to the present disclosure. Like connector assemblies 10 and 100 described herein, connector assembly 500 includes a first housing 502, a second housing 504 and a contact subassembly 506. The individual components and functions of connector assembly 500 are equivalent to those described with reference to connector assembly 200, except that the latching of first housing 502 with respect to second housing 504 is achieved with a centrally located deflectable latching member 572 formed on first housing 502 that is adapted to engage a latching slot 574 formed on second housing 504. The design, operation and functional/structural advantages of connector assembly 500 correspond to those described herein with respect to connector assemblies 10 and 100.
Turning to FIG. 10, a further advantageous implementation of the present disclosure is schematically depicted. Patch panel assembly 600 includes a first housing 602 that includes a plurality (6) ports 603 in side-by-side alignment. Each port 603 defines a first jack opening 608 for receipt of a plug. A second housing 604 includes a corresponding plurality (6) of ports 605 in side-by-side alignment, each port 605 defining a second jack opening 680. A contact subassembly 606 includes a plurality (6) of contact inserts 622 for introduction into jack openings 680. Contact inserts 622 are mounted with respect to a PCB 626, as are sets (6) of contact support members 612, 614, 616, 618. Latching structures 672 are provided on first housing 602 to facilitate mounting of first housing 602 with respect to second housing 604 (with contact subassembly 606 positioned therewithin or therebetween.
As will be readily apparent to persons skilled in the art, patch panel assembly 600 extends the electrical connection technology described herein above with reference to connector assemblies 10, 100, 500 to a patch panel environment. Thus, each of the port combinations 603, 605 functions as an individual connector assembly, in the sense of connector assemblies 10, 100, 500 described herein above. Each of ports 603 is adapted to receive/cooperate with a contact alignment according to the IEC 60603-7-7 standard, whereas each of ports 605 is adapted to receive/cooperate with a conventional RJ-45 contact alignment. Patch panel assembly extends the structural and functional advantages of the disclosed connector assemblies 10, 100, 500 to a multi-port application. Alternative patch panel designs and geometries, e.g., 12 port, 24 port, angled and/or arcuate patch panel assemblies, and the like, may benefit from the disclosed connector assembly technology. Further, preterminated plug/cable assemblies may be used in cooperation with the disclosed patch panel assembly 600 (and alternative multi-port assemblies) to achieve the benefits associated therewith.
Although the present disclosure has been described with reference to exemplary embodiments and implementations, it is to be understood that the present disclosure is neither limited by nor restricted to such exemplary embodiments and/or implementations. Rather, the present disclosure is susceptible to various modifications, enhancements and variations without departing from the spirit or scope of the present disclosure. Indeed, the present disclosure expressly encompasses such modifications, enhancements and variations as will be readily apparent to persons skilled in the art from the disclosure herein contained.