The present application relates generally to the field of electrical connectors, and more particularly to a solderless single pair Ethernet (SPE) connection system.
The following description is provided to assist the understanding of the reader. None of the information provided or references cited are admitted to be prior art.
Various types of connectors are used for forming connections between a wire and any manner of electronic or electrical component. For example, an electrical connection may be formed between a printed circuit board (PCB) of a controller and a sensor assembly. Traditionally, the electrical connection between a wire and (PCB) is formed by soldering the core of the wire onto an electrical pad or of the PCB. The wire may similarly be soldered to an electrical pad of the sensor assembly to form the electrical connection between the sensor assembly and the controller. This process can be tedious, inefficient, and undesirable and may result in a high scrap rate, which may be expensive. Moreover, once a solder has been made, the connection is not reparable, and a replacement would require new components. This is undesirable in applications where components cannot be easily reachable (e.g., a connection to a vehicle's PCB). Thus, a quick, efficient, and reliable device that can be used to connect two or more devices together for communication and/or power sharing therebetween is desirable.
The systems, methods, and devices of this disclosure each have several innovative aspects, no single one of which is solely responsible for the desirable attributes disclosed herein.
An solderless single pair Ethernet (SPE) connector is disclosed. In one implementation, the SPE connector includes a female connector portion and a male connector portion. The female connector portion includes a first electrical contact comprising a first press-fit pin and a first female portion, the first electrical contact positioned partially within a first insulative housing, a second electrical contact comprising a second press-fit pin and a second female portion, the second electrical contact positioned partially within the first insulative housing, and a first outer shield, the first outer shield mechanically secured to the first insulative housing. The male connector portion includes a third electrical contact comprising a first insulation displacement contact (IDC) portion and a first male portion, a fourth electrical contact comprising a second IDC portion and a second male portion, and a second outer shield, the second outer shield mechanically secured to a second insulative housing, the second insulative housing positioned at least partially around the third electrical contact and the fourth electrical contact.
In another implementation, a SPE connector may include a female connector portion and a male connector portion. The female connector portion includes a first contact having a first press-fit pin, a second contact comprising a second press-fit pin, and a first insulative housing having a first contact retention recess and a second contact retention recess. The first contact may be positioned at least partially within the first contact retention recess, and the second contact may similarly be positioned at least partially within the second contact retention recess. The first press-fit pin and the second press-fit pin extend from the first insulative housing and are configured to electrically and mechanically connect to respective openings of a printed circuit board. The male connector portion may include a first insulation displacement contact (IDC) and a second IDC, the first IDC configured to connect to a first wire of an SPE cable, and the second IDC configured to connect to a second wire of the SPE cable.
Another implementation relates to a method of use. The method may include aligning a first side of a female connector adjacent to a printed circuit board, compressing press-fit compliant pins of the female connector into respective conductive holes of the printed circuit board, aligning a first wire of a single pair Ethernet (SPE) wire adjacent to a first IDC contact of a male connector, aligning a second wire of the single pair Ethernet (SPE) wire adjacent to a second IDC contact of the male connector, compressing an insulative housing onto the first wire and the second wire such that a first electrical connection is made between the first wire and the first wire and a second electrical connection is made between the second wire and the second IDC, and adjoining the male connector with the female connector such that an electrical connection is formed between a first conductive hole of the printed circuit board and the first wire and an electrical connection is formed between a second conductive hole of the printed circuit board and the second wire.
The electrical connector is not limited by its number of wire openings or other components. Particular embodiments of electrical connectors are described in greater detail below by reference to the examples illustrated in the various drawings.
Reference will now be made to various embodiments, one or more examples of which are illustrated in the figures. The embodiments are provided by way of explanation of the invention and are not meant as a limitation of the invention. For example, features illustrated or described as part of one embodiment may be used with another embodiment to yield still a further embodiment. It is intended that the present application encompass these and other modifications and variations as come within the scope and spirit of the invention.
Disclosed herein is a single pair Ethernet (SPE) connector. The SPE connector can be used with a variety of corresponding connectors and electrical components. For example, the SPE connector may be used with a printed circuit board (PCB) and/or an electrical plug. In an embodiment, the SPE connector includes a male connector portion and a female connector portion. The female connector is configured to connect to a PCB via an electrical connection between press-fit ends of respective electrical contacts and the male connector is configured to connect to the two wires of a SPE cable via an insulation displacement end of respective electrical contacts. The female connector and the male connector are configured to mate together such that a first electrical connection between a first contact of the PCB and a first wire of the SPE cable is formed and a second electrical connection between a second contact of the PCB and a second wire of the SPE cable is formed.
It is to be appreciated that in other embodiments, similar techniques and structures may be used to form connections between a PCB and multiple SPE wires. For example, a main controller in a manufacturing environment may need to connect with multiple devices or sensors (e.g., robotic arms, cameras, temperature sensors, drives, etc.) to share power and/or communicate data. Accordingly, in such an environment, an SPE connector that is configured to connect 2, 3, 4, 5, or more wires to respective contacts on the PCB of the main controller may be implemented. That is, in some embodiments, the male connector and the female connector may include additional contacts to those discussed herein that allow for efficient, reliable, and removable electrical connections between multiple SPE cables and a respective PCB.
The unique design of the male connector and the female connector increases the versatility of the SPE connector. Specifically, the press-fit pins of the female connector allow for a secure and reliable connection to a respective PCB via through holes on the PCB without the use of solder or other tedious connection methods. Additionally, the male connector allows for an easy disconnection and reconnection of SPE cables to the female end and the IDC contact portions of the male connector allow for a user to efficiently and reliably make connections between the male connector and wires of the SPE (or other) cable. Accordingly, this versatility allows for a wide potential of options of connecting, reconnecting, replacing, and/or adding connections between devices. For example, traditionally, a user must manually handle each wire and solder the wire to a contact pad of the PCB, the PCB must be pre-fabricated to accept a particular plug or socket, and/or the SPE cable must be stripped and connected and secured to a corresponding plug or socket. However, the design for this SPE connector allows for an SPE cable to be connected and/or disconnected to a PCB board efficiently and reliably, which allows for versatility in, for example, a multifaceted application such as an industrial application where updates, changes, and inclusion of devices within a system are ever changing. In addition, the design of the SPE ensures a reliable electrical connection between PCB and wires (e.g., via the press-fit pins and mechanical interlocks) that are resistant to thermal changes and/or vibrations that could cause a soldered electrical connection to crack, rust, and/or break, which is advantageous in, for example, particular applications such as in vehicles where there are fulgurations in temperature and mechanical vibrations are present.
Moreover, and in particular, to communications connections such as Ethernet, the SPE connector allows for a single pair of conductive wires to transmit data while simultaneously delivering power between devices. The shielding components of the SPE connector ensure data communication integrity by reducing potential electromagnetic interference and the electrical connections via the press-fit pins ensure that heat due to power transmission does not affect the integrity of the electrical connections, which also enhances the durability of a system implementing the SPE connector.
Various embodiments of an SPE connector and various corresponding electrical components are illustrated throughout
In some embodiments, the male connector 110 and the female connector 111 may be mechanically secured together via a latching mechanism 180. The latching mechanism 180 includes an opening 190 on a shielding of the female connector 111 and an interlock pin 191 of the male connector 110 such that the interlock pin 191 the interlock pin 191 is configured to adjoin with the opening on the shield and create a secure mechanical connection between the male connector 110 and the female connector 111 (e.g., via a frictional force). In some embodiments, the SPE connector 101 may include multiple latching mechanisms that are configured to mechanically secure the male connector 110 and the female connector 111 together. The latching mechanism 180 ensures that the electrical connection between the PCB 103 and the SPE cable 102 is reliable in variable conditions.
The female connector 111 is mechanically secured to the PCB 103 via a second latching mechanism 181. The second latching mechanism 181 includes a first pin 112 and a second pin 113 on the female connector 111 configured to be deployed into a first opening and a second opening of the PCB 103, respectively, to mechanically secure the female connector 111 to the PCB 103. In other embodiments, the latching mechanism 180 and the second latching mechanism 181 may have alternative or additional components that allow for the respective mechanical connections. The latching mechanism 180 and the second latching mechanism 181 are discussed in additional detail below.
In some embodiments, the male connector 110 and the female connector 111 of SPE connector 171 are mechanically secured together via latching mechanism 180. Latching mechanism 180 of
As further illustrated in
The female connector 211 includes an outer shield 220, an insulative housing 221, first contact 222, and a second contact. The outer shield 220 is configured to block or attenuate electromagnetic radiation to reduce interference with the data signals sent via the first contact 222 and the second contact. That is, the outer shield 220 is configured to sufficiently encapsulate the insulative housing 221 in order to provide structural protection to the insulative housing 221 and shield the contacts seated within the insulative housing 221 from electromagnetic radiation. The outer shield 220 may not cover one side of the insulative housing 221 that is structured to receive a corresponding side of the male connector 210. The outer shield 220 may be made of copper, nickel, an alloy thereof or any conductive material that is configured to attenuate or block electromagnetic radiation. The thickness of the shield may be selected based on the application and materials used.
The insulative housing 221 includes recesses that house the first contact 222 and the second contact. For example, the recesses are configured to provide support to a respective contact. The recesses have a depth that allows for the respective contact to be seated therein. A gap 285 between the insulative housing 221 and the outer shield 220 allows for a corresponding interlock pin of the male connector 210 to be placed therein and create a secure mechanical connection therebetween. In an embodiment, the recesses include a saddle seat portion 223 that is configured to seat a “U” shaped portion of the respective contact (e.g., first contact 222). The seating of the first contact 222 the saddle seat portion 223 restricts the first contact 222 from lateral movements and ensures that a respective press-fit pin can be mated with the through-hole 240 on the PCB 204 reliably and efficiently.
The first contact 222 includes a press-fit pin 250 on a first end (e.g., a press-fit portion) and is shaped such that a second end 229 (e.g., a female portion) creates a pinch-point for a pin or blade of a respective first contact 232 of the male connector 210 when placed within the insulative housing 221. The frictional force with the pin or blade of the respective first contact 232 forms a mechanical and electrical connection is formed therebetween. The press-fit pin 250 is configured to create a frictional force between a through-hole having an electrical pad or conductive plating 240 of a PCB 204. The frictional force may be created via an elastic force created when the press-fit pin 250 is place within the through-hole 240. The press-fit pin 250 is structured such that when the press-fit pin 250 is inserted into a respective through-hole, deformation occurs between the press-fit pin 250 and the through-hole to create a mechanical and electrical connection therebetween. Additional features of the first contact 222 of the female connector 211 are described below.
The male connector 210 includes the first contact 232 and a second contact. The first contact 232 of the male connector 210 includes an insulation displacement contact (IDC) at a first end and the pin or blade at second end. The IDC is configured to displace the insulation of a corresponding first wire 290 of a SPE cable 205 in order to create a mechanical and electrical connection therebetween. The male connector 210 also includes a first insulative housing 260 and a second insulative housing 261. The first insulative housing 260 is configured to provide support to the first contact 232 and the second contact of the male connector 210. The second insulative housing 261 is structured such that, for example, the first wire 290 can be adjoined with the IDC when the second insulative housing 261 is pressed over or onto the first contact and the second contact of the male connector 210.
The male connector 210 also includes an outer shield 265. The outer shield 265 of the male connector 210 encapsulates at least a portion of the first and second insulative housing 260 and 261 and includes a first opening that allows the first contact 232 and the second contact of the male connector 210 to be adjoined with the female connector 211 and a second opening that allows the SPE cable 205 to be adjoined with the contacts of the male connector 210. The outer shield 265 of the male connector 210 may be formed or made form a similar material to the outer shield 220 of the female connector 211 and provide radio frequency (RF) shielding to the electrical components within the outer shield 265. In an embodiment, the outer shield 265 is mechanically secured to the first and second insulative housings 260 and 261, for example, by virtue of the partial encapsulation thereof.
Similar to that of
The outer shield 310 also includes a first tongue 330 and a second tongue 331 positioned on opposite sides of the outer shield 310. The first tongue 330 and the second tongue 331 are structured to provide tactile support to a user. For example, the first and second tongues 330 and 331 may allow for a user to grab the outer shield 310 via placing one or more fingers between the respective pins 321 and 322 in order to compress the female connector 301 and press-fit pins together with the PCB 304. Moreover, the outer shield 310 includes a first locking pin 380 and a second locking pin 381. The first locking pin 380 and the second locking pin 381 are structured to be seated within corresponding notches of the insulative housing 311. In this way, the first and second locking pins 380 and 381 may secure the insulative housing 311 in a manner that prevents movement of the insulative housing 311 along a first axis (e.g., longitudinal axis) relative to the outer shield 310. Further, the snug fit between a base portion of the insulative housing 311 and the outer shield 310 prevents the movement of the insulative housing 311 along a second axis (e.g., vertical axis) and a third axis (e.g., lateral axis) such that a corresponding male connector can be adjoined to the female connector 301 reliably and efficiently.
In some embodiments, the outer shield 310 also includes an opening 351 on a third side that allows for a interlock pin of a respective male connector to mechanically secure the male connector with the female connector 301. The third side may also include an indented ridge 349 that runs the length of the female connector 301 that is structured to act as a groove in order assist in the assembly of the insulative housing 311 and the outer shield 310 and provide support to the insulative housing 311. Moreover, the indented ridge 349 acts as an inadvertent error prevention feature to ensure the housing cannot be inserted into the shield in improper configuration (e.g., upside down) and that a respective male connector is inserted correctly. The indented ridge 349 may also include a guide rail 369 that extends angularly away from the edge of the indented ridge 349 on the third side from the outer shield 310. The rail 369 may ensure that the interlock pin of the respective male connector is guided within a cage structure (e.g., under the indented ridge 349) created by the outer shield 310. The outer shield 310 also includes an end portion 375 that is discussed in additional detail in reference to
The outer shield 310 of
The outer shield 401 may be pre-fabricated or otherwise constructed to form a cage-like structure that is configured to receive the insulative housing 402 and mechanically secure the insulative housing 402 therein. In an embodiment, a first tongue 410 may be designed to apply a force to a surface 420 and a second tongue on an opposite side of the outer shield may be designed to apply an opposing force to provide lateral support the insulative housing. In an alternative embodiment, the surface 420 may be a groove. For example, the outer shield 401 may include the first tongue 410 that is designed to be seated within a groove 420 of the insulative housing 402 in order to guide and position the insulative housing 402 within the cage-like structure of the outer shield 401. Similarly, in an example embodiment, the outer shield 401 may include the second tongue formed in a side of the cage like structure opposite from the first tongue 411 that is designed to be seated within a corresponding second grove of the insulative housing 402 positioned on a side opposite the groove. In some embodiments, the first and second tongues may be configured to be displaced from the groove by a respective male connector when the male connector is inserted and/or latch with corresponding dimples of the male connector to mechanically secure the female and male connectors together. In some embodiments, the first tongue 411, the second tongue, and the cage-like structure 490 may be formed of a single element or material.
The outer shield 401 may also include a first pin 464 that is designed to be seated within a first notch 430 of the insulative housing 402 such that the insulative housing 402 is mechanically secured within the outer shield 401 once the first pin 464 locks with the first notch 430. Similarly, the outer shield 401 may include a second pin positioned on a side opposite the first pin 464 that is designed to be seated within a second notch of the insulative housing 402 positioned on a side opposite the first notch 430.
The insulative housing 402 may include a tapered portion 470, a nose portion 471, and a base portion 472. The base portion 472 may include the first notch 430 and the second notch positioned on sides opposite from one another. The base portion 472 may also include an anvil 482. The anvil 482 may extend away perpendicularly relative to an axis 499 of the insulative housing 402. The anvil 482 is designed to provide support to a hinge portion 469 of the outer shield 401 such that an end portion 468 of the outer shield 401 can be closed when the insulative housing 402 is moved along the axis 499 to a position within the outer shield 401. The base portion 472 may be sized such that the base portion 472 fits snug within the cage-like structure of the outer shield 401. Further, the anvil 482 may be sized and positioned such that fits within the indented ridge of the outer shield 401. The nose portion 471 extends from the base portion 472 along the axis 499 and is sized such that there is room between the cage-like structure 490 and the nose portion 471 to allow for a corresponding portion of a male connecter to also be positioned within the cage-like structure. The tapered portion 470 extends from the nose portion 471 along the axis 499 and is tapered to a smaller size than the nose portion 471. The tapered portion 470 may assist with guiding a corresponding male connector around the nose portion 471.
The first contact 403 and the second contact 404 may be similar in structure. For example, the first and second contact 403 and 404 may include a press-fit pin 415 at a first end and a contact tine 416 at a second, distal end. In some embodiments, the first and second contact 403 and 404 may include a different type of contact at the second end. For example, the second end may include a socket or interlock contact. The press-fit pin 415 is structured to protrude from the female connector (e.g., past the outer shield 401) and retention ribs provide support from all lateral movements in order for the press-fit pin 415 to be compressed into a corresponding PCB hole 444 without damaging the components. Contact tine 416 is structured such that the contact tine 416 is positioned near a bottom of a respective recess in the insulative housing 402 to create a pinch point therebetween. The pinch point causes the contact tine 416 to compress a corresponding pin or blade of an IDC contact of a respective male contact. The compression ensures a reliable and secure electrical mechanical connection therebetween. The structure of the first and second contact 403 and 404 is also discussed in reference to
The outer shield 401 further includes an end portion 475 that is connected to a main body portion of the outer shield 401 by a transition portion 476. In an embodiment, the transition portion 476 comprises a portion smaller in width than the end portion 475 that may be subsequently bent or folded to position the end portion 475 perpendicular to the respective surfaces of the main body portion of the outer shield 401. Respective extension portions extend from the end portion 475 and are bent approximately 90 degrees relative to a primary plane of the end portion 475 such that the extension portions may overlap sides of the main body portion of the outer shield 401.
The first contact 403 and the second contact 404 of
Referring generally to
Still referring to
The deflection end 530 includes a deflective contact tine 416 that extends from an end (i.e., the transition base 536) of the transition portion 531 that is opposite from the where the press-fit pin 416 extends from. The deflective contact tine 416 extends from the transition base 536 to a distal end in a direction that is non-parallel to direction the press-fit pin 415 extends. The deflective contact tine 416 may extend from the transition base 536 in a direction perpendicular the direction which the press-fit compliant pin extends 415. The deflective contact tine 416 may then further extend along a first angular plane that is obtuse to the plane in which the press-fit pin extends. For example, the deflective contact tine 416 may extend toward or past a plane defined tangentially at the bottom of the “U” shape of the transition base 536. Such a configuration may ensure that the distal end of the contact tine 416 is positioned near the bottom or against the bottom of a respective recess in the insulative housing 402 such as to create a pinch-point therebetween. The pinch-point, when a corresponding pin of the male connector is inserted, causes the transition base 536 and/or the deflective contact tine 416 to deflect and compress the corresponding pin. In some embodiments, the contact tine 416 extends from the transition portion 531 a distance and then curves such that the contact tine 416 includes a dip or curve at the distal end. In other words, the deflective contact tine 416 extends from the transition portion 531 a distance along the angular plane described above, then further along a second angular plane that is greater relative to the plane in which the press-fit compliant pin 415 extends, and further along a third angular plane that is lesser than the relative to the plane in which the press-fit compliant pin 415 extends. The curvature 580 near the distal end of the contact tine 416 may create a pinch-point with the bottom of the respective recess such that a respective pin or blade is compressed when inserted therebetween. Moreover, the curvature 580 may ensure that a respective pin or blade can reliably and efficiently be positioned in the pinch-point via sliding under the distal end of the deflective contact tine 416. In alternative embodiments, the deflection end 530 may be any configuration that allows for the first and second contacts 403 and 404 to create a mechanical and electrical connection between a corresponding pin or blade of a male connector and the respective first or second contact 403 or 404.
Moreover, the first and second contacts 403 and 404 may also include two retention ribs 520 that extend outwards from the press-fit base 537 near the connection with the female-end base 536. The retention ribs 520 both restrict how far the first and second contacts 403 and 404 may be inserted into a recess of an insulative housing and also provide a structural support for the contact by mechanically touching the inside of the recess of the insulative housing and thereby preventing lateral movements.
Referring generally to
The outer shield 401 includes a first arm 549 that extends from an edge on a first side of the cage-like structure to a first latching pin 551 and a second arm 552 that extends from the edge on a second side opposite the first side to a second latching pin 553. The first arm 549 extends away from the edge in a “U” shape such that the arm extends further from the “U” shaped portion along a plane parallel to the first side along the first side to the second latching pin 553. Similarly, the first arm 549 extends away from the edge in a “U” shape such that the arm extends further from the “U” shaped portion along a plane parallel to the second side along the second side to the second latching pin 553. The shape and structure of first and second arms 549 and 552 allow a user to press down on the arms to compress the first and second latching pins 551 and 553 into respective holes on the PCB. The first and second latching pin 551 and 553 extend in a direction perpendicular to the first and second arms 549 and 552 in a direction that is parallel to the direction in which the press-fit pins of the contacts extend when the contacts are placed within the outer shield 401.
The first and second latching pins 551 and 553 may have similar structure. For example, the latching pins 551 and 553 include a gap 554 that extends from a distal end of the pin, retention ridges 555 that extend outward from sides of the pins, and stop ridges 556 that extend similarly from the sides of the pins. The gap 554 allows for the respective latching pin to be compressed into a through-hole on the PCB. The retention ridges 555 ensure that the latching pin mechanically secures the outer shield 401 to the PCB. The stop ridges 556 prevent the latching pin from over insertion into the PCB. In this way, the structure of the latching pins 551 and 553 allows for them to be inserted into respective through-holes of a PCB to reliably and efficiently mechanically secure the female connector to the PCB.
Female connector 400 further includes various latching pins (e.g., latching pin 421). In an embodiment, latching pin 421 (as well as one or more of the other latching pins) includes first and second prongs 633 and 634 that may be configured such that they may be compressed when engaged with an opening of a corresponding PCB. Each prong 633, 634 includes an upper retention knob 636 and a lower retention knob 638 to position the female connector 400 at a desired distance from the PCB upon full engagement of the female connector (and corresponding latching pins) with the PCB. In an embodiment, the distance between the upper retention know 636 and the lower retention knob 638 approximates or is slightly greater than an depth of the PCB such that, upon engagement of the latching pin with the PCB, the upper retention knob 636 will be seated adjacent an upper surface of the PCB and the lower retention knob 638 will be seated adjacent a lower surface of the PCB.
The interlock arm 701 extends outwardly from an edge of the opening 710 of the shield 720 in a curved shape and back toward an opposite end of the connector in a plane parallel to an adjacent surface of the connector. The curved shape allows for the interlocking arm 701 to flex when inserted into a corresponding portion of a female connector and to engage an interlocking pin portion 711 with a corresponding notch or opening of the female connector thereby latching the connectors together. In an embodiment, the interlocking pin portion 711 includes respective wings folded off of opposite sides of an central portion of the interlock arm 701. The wings may be symmetrical about the central portion of the interlock arm 701.
The first insulative housing 804 includes a first contact retention opening 850 structured to form to and support the first IDC contact 802 and a second contact retention opening 851 structured to form to and support the second IDC contact 803. The first insulative housing 804 includes an insulated base 849 that is structured to provide an insulated buffer between the outer shield 801 and the IDC contacts 803 and 804 when the IDC contacts are inserted into respective contact retention openings 850 and 851. The insulated base 849 also provides mechanical support to the IDC contacts, for example, when the IDC contacts 802 and 803 are connected to or compressed with respective wires.
The first and second IDC contacts 802 and 803 include an IDC portion 870 and a pin or blade portion 871. The IDC portion 870 is structured to displace insulation from a respective wire 872 or 874 of an SPE cable 890 and form an electrical and mechanical connection therebetween. For example, a first wire 874 of the SPE cable 890 may be compressed between a first blade 884 and second blade 885 of the IDC portion 870 and the first and second blades 884 and 885 may displace the insulation of the first wire 874 and form an electrical and mechanical connection with the conductive core of the first wire 874. The second insulative housing 805 is structured such that when the second insulative housing 805 is placed and compressed onto the base portion 810 and IDC contacts 802 and 803, the second insulative housing 805 compresses the wires 872 and 874 with the IDC portions of the IDC contacts 802 and 803. Further, the second insulative housing 805 is structured to compress the SPE cable 890 into the wire retention portion 844 such that the wire retention portion 844 forms a mechanical connection with the outer portion of the SPE cable 890. For example, the mechanical connection enhances that the integrity and durability of the SPE connector by ensuring that the wires of SPE cable 890 maintain electrical and mechanical connections with the respective IDC contacts 802 and 803.
The insulative housing 901 may also include a first cutaway 921, a second cutaway 922, and a third cutaway 923. The second cutaway 922 is structured to allow male portions of corresponding IDC contacts to protrude out from the insulated housing 901 when assembled. The first cutaway 921 and the third cutaway 923 such that a second insulative housing that supports and insulates the IDC contacts from an outer shield can be interlocked with the insulative housing 901 when assembled as a male connector. For example, the base portion of the second insulative housing may include butterflied sides that are configured to interlock with the first cutaway 921 and the third cutaway 923 such that the insulative housing and the second insulative housing are mechanically secured together.
In an operation 1401, a first side of a female connector is aligned adjacent to a printed circuit board. In an embodiment, the female connector is aligned adjacent to the PCB such that press-fit compliant pins are aligned with respective holes and one or more latching pins are aligned with respective through-holes on the PCB. In alternative embodiments, the connector may utilize contact pins that create an interference fit with a contact pin on the PCB such that press-fit compliant pins are not utilized. In some embodiments, an insulative housing having contacts therein may first be placed into an outer shield of the female contact and an end portion may be hinged or folded into a close position such that the outer shield is mechanically secured to the insulative housing of the female connector.
In an operation 1402, press-fit compliant pins of the female connector are compressed into respective conductive holes of the printed circuit board. The female connector is compressed together with the PCB such that the press-fit compliant pins deform and reform in order to lock into the respective conductive holes. Similarly, the latching pins may deform, reform, and lock into respective through-holes. The latching pins and the press-fit pins create a reliable mechanical connection between the female connector and the PCB. In an alternative embodiment where press-fit compliant pins are not used, the pins of the female connector are compressed against contact pads on the PCT. This operation may be performed in conjunction with compressing of the insulating housing or other components onto the PCB.
In an operation 1403, a first wire of a single pair Ethernet (SPE) cable is aligned adjacent to a first IDC contact of a male connector. In an operation 1404, a second wire of the single pair Ethernet (SPE) cable is aligned adjacent to a second IDC contact of the male connector. In an embodiment, the first and second wires are positioned over blades of the respective IDC contacts such that when the wires are compressed together with the IDC, the wires are compressed between the blades. Moreover, the SPE cable may be positioned adjacent to a wire retention portion of the male connector such that when the SPE cable is compressed together with the wire retention portion, the retention portions causes the male connector to mechanically secure to the SPE cable via a frictional force. In alternative embodiments, a crimp portion of an outer shield may be used in lieu of the wire retention portion and the crimp portion may be crimped about at least a portion of the SPE cable.
In an operation 1405, an insulative housing is compressed onto the first wire and the second wire such that a first electrical connection is made between the first wire and the first wire and a second electrical connection is made between the second wire and the second IDC. In an embodiment, the insulative housing is positioned adjacent to the IDC contacts and the first and second wire and compressed onto the IDC contacts and the first and second wires such that the first and second wires are forced into respective blades of the IDC contacts, thereby causing the insulation of the first and second wires to displace and an electrical and mechanical connection to form therebetween. Moreover, the SPE cable may be forced, via the compression of the insulative housing, into the wire retention portion such that a second point of mechanical connection between the SPE cable and the male connector is formed via a frictional force.
Moreover, in an embodiment, once the insulative housing is compressed onto the IDC contacts, the insulative housing may be mechanically secured to an outer shield of male connector such that the insulative housing and the IDC contacts are at least partially encapsulated within the outer shield. For example, the insulated housing may be compressed onto the IDC contacts that are positioned on a base portion of the outer shield. A first portion (e.g., a first wing) of the outer shield may then be folded up and/or around the insulative housing and a second portion (e.g., a second wing) may be folded up and/or around the insulative housing such that the insulative housing and IDC contacts are mechanically secured therein. In some embodiments, the first portion and the second portion are made from a flexible material that can be deformed in order to wrap around the insulative housing. In this configuration, the insulative housing is mechanically secured to the outer shield at least by the wire retention portion, the base portion, the first portion, and the second portion of the outer shield. The encapsulation by the outer shield provides RF protection to the contacts positioned therein to ensure the integrity of any electrical signals carried by the IDC contacts.
In an operation 1406, the male connector is adjoined with the female connector such that an electrical connection is formed between a first conductive hole of the printed circuit board and the first wire and an electrical connection is formed between a second conductive hole of the printed circuit board and the second wire. In an embodiment, the male connector is positioned adjacent to the female connector such that pins of the male connector are aligned with an opening of the recesses of the female connector. The male connector is compressed into the female connector such that an electrical and mechanical connection of contacts of the male connector is formed with respective contacts in the female connector. In some embodiments, a latching pin of the male connector may mate with an opening on the female connector in order to mechanically secure the male connector with the female connector.
With respect to the use of substantially any plural and/or singular terms herein, those having skill in the art can translate from the plural to the singular and/or from the singular to the plural as is appropriate to the context and/or application. The various singular/plural permutations may be expressly set forth herein for sake of clarity.
It will be understood by those within the art that, in general, terms used herein, and especially in the appended claims (e.g., bodies of the appended claims) are generally intended as “open” terms (e.g., the term “including” should be interpreted as “including but not limited to,” the term “having” should be interpreted as “having at least,” the term “includes” should be interpreted as “includes but is not limited to,” etc.) It will be further understood by those skilled in the art that if a specific number of an introduced claim recitation is intended, such an intent will be explicitly recited in the claim, and in the absence of such recitation no such intent is present. For example, as an aid to understanding, the following appended claims may contain usage of the introductory phrases “at least one” and “one or more” to introduce claim recitations. However, the use of such phrases should not be construed to imply that the introduction of a claim recitation by the indefinite articles “a” or “an” limits any particular claim containing such introduced claim recitation to inventions containing only one such recitation, even when the same claim includes the introductory phrases “one or more” or “at least one” and indefinite articles such as “a” or “an” (e.g., “a” and/or “an” should typically be interpreted to mean “at least one” or “one or more”); the same holds true for the use of definite articles used to introduce claim recitations. In addition, even if a specific number of an introduced claim recitation is explicitly recited, those skilled in the art will recognize that such recitation should typically be interpreted to mean at least the recited number (e.g., the bare recitation of “two recitations,” without other modifiers, typically means at least two recitations, or two or more recitations). Furthermore, in those instances where a convention analogous to “at least one of A, B, and C, etc.” is used, in general such a construction is intended in the sense one having skill in the art would understand the convention (e.g., “a system having at least one of A, B, and C” would include but not be limited to systems that have A alone, B alone, C alone, A and B together, A and C together, B and C together, and/or A, B, and C together, etc.) In instances where a convention analogous to “at least one of A, B, or C, etc.” is used, in general such a construction is intended in the sense one having skill in the art would understand the convention (e.g., “a system having at least one of A, B, or C” would include but not be limited to systems that have A alone, B alone, C alone, A and B together, A and C together, B and C together, and/or A, B, and C together, etc.) It will be further understood by those within the art that virtually any disjunctive word and/or phrase presenting two or more alternative terms, whether in the description, claims, or drawings, should be understood to contemplate the possibilities of including one of the terms, either of the terms, or both terms. For example, the phrase “A or B” will be understood to include the possibilities of “A” or “B” or “A and B.”
The foregoing description of illustrative embodiments has been presented for purposes of illustration and of description. It is not intended to be exhaustive or limiting with respect to the precise form disclosed, and modifications and variations are possible in light of the above teachings or may be acquired from practice of the disclosed embodiments. It is intended that the scope of the invention be defined by the claims appended hereto and their equivalents.
The present application claims priority to and the benefit of U.S. Provisional App. No. 63/082,724, filed Sep. 24, 2020, the entirety of which is hereby incorporated by reference in its entirety.
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