The present invention is directed to an impedance control connector. In particular, the invention is directed to an impedance control connector which provides a stable transition zone impedance for twisted pair connector with long untwisted portion.
Maintaining signal integrity in communications is always desired. Factors that affect signal integrity include cable design and the process that is used to terminate or attach a cable. Cables are typically made of at least one plated center conductor covered by a dielectric and a braid and/or foil shield protector with an overall non-conductive jacket. The termination of the braid onto a device, such as a printed circuit board (PCB) or a connector, can significantly affect cable performance.
Various methods are known to terminate shield connectors, including soldering the end of the wire onto a PCB/connector termination, laser terminating parallel gap resistance welding. Another common method of termination is to use a ferrule. One significant problem with a ferrule is that crimping the wire to apply the ferrule tends to crush the cable dielectric. Another problem with existing methods of terminating a braid is that they can tend to rearrange the placement of the differential pair within the cable jacket. Both problems can affect impedance and other electrical parameters, which affect signal integrity.
In addition, due to the decreased size and increased function of these connectors, it is difficult to have effective connector position assurance devices and terminal position assurance devices which meet the force requirements for different industries, such as, the automotive industry.
It would be, therefore, beneficial to provide an electrical connector which controls impedance and which does not damage or rearrange the conductors of the cable. It would be beneficial to provide an electrical connector in which a visible and mechanical indication is provided that the terminals are properly positioned and secured in the housing.
An embodiment is directed to a terminal for terminating a shielded cable in a connector assembly. The terminal has a conductor receiving section and a mating terminal receiving section. The mating terminal receiving section has a lead-in portion and securing projections. At least one longitudinally extending opening is positioned about the circumference of the mating terminal receiving section, the opening reduces the cross section of the terminal. The opening provides impedance tuning to allow for a defined pitch of the terminal to be maintained without an impedance drop because of the close proximity of the terminal to an adjacent terminal.
An embodiment is directed to a connector assembly which controls impedance. The connector assembly includes a first metallic outer housing and a second metallic outer housing. The second metallic housing has a conductor receiving portion. A rib is formed in the conductor receiving portion, the rib extends in a direction which is parallel to a longitudinal axis of the second metallic outer shell.
An embodiment is directed to a connector housing assembly. The housing assembly has a mating end and an oppositely facing conductor receiving end. A top wall, a bottom wall and side walls extend between the mating end and the conductor receiving end. A connector receiving passage extends between the mating end and the conductor receiving end. An impedance controlled connector assembly is positioned in the connector receiving passage. The connector assembly has a first metallic outer housing or shell and a second metallic outer housing or shell. The first metallic outer shell has a stamped and formed recess which extends about the circumference of the first metallic outer shell, the recess provides controlled impedance of the first metallic outer shell in the area of the recess. A latch having an engagement projection extends from the top wall, the engagement projection has a mating engagement surface. A connector position assurance receiving recess extends from the top wall. A connector position assurance device is positioned in the connector position assurance receiving recess. The connector position assurance device has a base portion and a resiliently deformable beam which extends from the base portion. A lockout projection engagement member extends from the beam. The lockout projection engagement member has a cam or sloped surface configured to cooperate with the mating engagement surface of the engagement projection of the latch.
An embodiment is directed to a connector housing assembly. The housing assembly has a mating end and an oppositely facing conductor receiving end. A top wall, a bottom wall and side walls extend between the mating end and the conductor receiving end. A connector receiving passage extends between the mating end and the conductor receiving end. An impedance controlled connector assembly is positioned in the connector receiving passage. The connector assembly has a first metallic outer housing or shell and a second metallic outer housing or shell. The first metallic outer shell has a stamped and formed recess which extends about the circumference of the first metallic outer shell, the recess provides controlled impedance of the first metallic outer shell in the area of the recess. A terminal position assurance receiving recess extending from a side wall. A terminal position assurance device is positioned in the terminal position assurance receiving recess. The terminal position assurance device has a base with a first surface and an oppositely facing second surface. A first terminal engagement section and second terminal engagement arms extend from the first surface in a direction away from the second surface.
Other features and advantages of the present invention will be apparent from the following more detailed description of the preferred embodiment, taken in conjunction with the accompanying drawings which illustrate, by way of example, the principles of the invention.
The description of illustrative embodiments according to principles of the present invention is intended to be read in connection with the accompanying drawings, which are to be considered part of the entire written description. In the description of embodiments of the invention disclosed herein, any reference to direction or orientation is merely intended for convenience of description and is not intended in any way to limit the scope of the present invention. Relative terms such as “lower,” “upper,” “horizontal,” “vertical,” “above,” “below,” “up,” “down,” “top” and “bottom” as well as derivative thereof (e.g., “horizontally,” “downwardly,” “upwardly,” etc.) should be construed to refer to the orientation as then described or as shown in the drawing under discussion. These relative terms are for convenience of description only and do not require that the apparatus be constructed or operated in a particular orientation unless explicitly indicated as such. Terms such as “attached,” “affixed,” “connected,” “coupled,” “interconnected,” and similar refer to a relationship wherein structures are secured or attached to one another either directly or indirectly through intervening structures, as well as both movable or rigid attachments or relationships, unless expressly described otherwise.
Moreover, the features and benefits of the invention are illustrated by reference to the preferred embodiments. Accordingly, the invention expressly should not be limited to such embodiments illustrating some possible non-limiting combination of features that may exist alone or in other combinations of features, the scope of the invention being defined by the claims appended hereto.
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With the connector 10 properly assembled the connector is mated to a mating connector 300. As illustrative mating connector 300, as shown in
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The rib 50 divides the conductor receiving portion 44 into two conductor receiving passages 54, 56. The conductor receiving passages 54, 56 are dimensioned to allow for the insertion of the terminals 60 therethrough.
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When assembled, as shown in
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With the terminals 60 properly terminated to the conductors 20, 22, the terminals 60 are inserted through the cable securing portion 46. The terminals 60 are then inserted through the conductor receiving passages 54, 56 of the conductor receiving portion 44 and into terminal receiving openings 57, 58 of the dielectric housing 51 positioned in the first outer shell 32. Barbs or projections 66 of the terminals 60 engage and displace material in the terminal receiving openings 57, 58, thereby retaining the terminals 60 in the terminal receiving openings 57, 58.
With the terminals 60 properly secured, the conductors 20, 22 are positioned in the conductor receiving portion 44 of the second metallic outer shell 34, with the exposed portion 23 (
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The positioning of the conductors 20, 22 in the conductor receiving passages 54, 56 maintains the proper positioning and desired spacing of the conductors 20, 22. In the illustrative embodiment, the conductors 20, 22 in the conductor receiving passages 54, 56 extend substantially parallel to each other and in substantially the same plane. As the conductor receiving portion 44 of the outer shell 34 surrounds the conductors 20, 22, as shown in
As the configuration and positioning of the rib 50 of the second metallic outer shell 34 is precisely controlled during the manufacturing process, the impedance in the conductor receiving portion 44 of the outer shell 34 can be tailored to match or approximately match the impedance of the cable 12, thereby optimizing the performance of the cable 12 and the electrical connector 10. In addition, the impedance in the conductor receiving portion 44 of the outer shell 34 can also be tailored by properly selecting the material used for the rib 50.
The second metallic outer shell 34 is secured to the cable 12 by the third metallic outer shell 31. As shown in
The electrical connector 10, and in particular, the outer shell 34 and the rib 50, provides impedance control and does not damage or rearrange the conductors 20, 22. By properly selecting the material used for the rib 50 and properly determining the spacing between the conductor receiving passages 54, 56, the conductors 20, 22 are properly positioned and the impedance of the connector 10 can be tailored to match or approximately match the impedance of the cable 12, thereby optimizing the performance of the cable 12 and the electrical connector 10.
Referring to
A latch or latch arm 120 having an engagement projection 122 extends from the top wall 106. In the embodiment shown, the latch 120 is connected to the top wall 106 proximate the mating end 102 and extends toward the conductor receiving end 104. The latch 120 is used to latch and secure the first housing assembly 100 to the second housing assembly 200, as will be more fully described below.
A connector position assurance receiving recess 124 is positioned proximate the top wall 106. Securing projections 126 extend into the connector position assurance receiving recess 124 proximate the conductor receiving end 104. The securing projections 126 are provided on either side of the latch 120.
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When properly mated together, the engagement projection 122 of the latch 120 cooperates with and is positioned in the latch-receiving opening 203 to secure the second housing assembly 200 with the first housing assembly 100.
A connector position assurance device 130 is maintained in the connector position assurance receiving recess 124 and is movable between a first position or open position, as shown in
The connector position assurance device 130 has a base portion 132 and a resiliently deformable beam 134 which extend from the base portion 132. The base portion 132 has a base front end 140 and a base back end 142. The beam 134 extends from the front end 140 in a direction away from the back end 142. The back end 142 is configured to allow an operator to manually engage or activate the connector position assurance device 130.
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In the pre-mated, open or first position, the latch 120 is in an undeflected position. The connector position assurance device 130 is maintained in the pre-mated, open or first position by the cooperation of the latching projections 162 with securing projections 126 which extend into connector position assurance receiving recess 124.
In the initial position, the movement of the connector position assurance device 130 toward the second position is prohibited unless the first housing assembly 100 is properly mated with the second housing assembly 200. If the first housing assembly 100 is not properly mated with the second housing assembly 200, the engagement surface 150 of the lockout engagement member 144 of the beam 134 of the connector position assurance device 130 remains in engagement with the engagement surface 152 of the engagement projection 122 of the latch 120, thereby preventing the movement of the connector position assurance device 130 to the second position.
As the first housing assembly 100 is mated with the second housing assembly 200, the latch engagement section 202 of the second housing assembly 200 engages the engagement projection 122 of the latch 120, forcing the engagement projection 122 of the latch 120 to move toward the top wall 106.
As insertion continues, the latch engagement section 202 of the second housing assembly 200 engages the cam or sloped surface 148, forcing the lockout projection engagement member 144 and the beam 134 toward the top wall 106. This causes the engagement surface 150 of the lockout engagement member 144 of the beam 134 of the connector position assurance device 120 to be removed from the engagement surface 152 of the engagement projection 122 of the latch 120, thereby allowing the latch 120 to move relative to the beam 134 of the connector position assurance device 120.
Continued insertion forces the latch engagement section 202 to move past the engagement projection 122 of the latch 120, allowing the latch 120 to return to an unstressed position. With the latch 120 returned to the unstressed position and the lockout projection engagement member 144 and the beam 134 moved toward the top wall 106, the connector position assurance device 130 is pushed, in a direction toward the mating end 102 of the first housing assembly 100 by the operator, to the mated, second or inserted position (
If the first housing assembly 100 and the second housing assembly 200 are not fully mated, the lockout projection engagement member 144 and the beam 134 will not be fully depressed, thereby preventing the movement of the resiliently deformable beam 134 and the lockout projection engagement member 144. Consequently, continued insertion of the connector position assurance device 130 will be prevented by the cooperation of the engagement surface 150 of the lockout projection engagement members 144 with the mating engagement surface 12 of the engagement projection 122.
With the lockout projection engagement member 144 and the beam 134 properly deflected, the movement of the connector position assurance device 130 from the first position (
The connector position assurance device 130 is maintained in the mated, closed or second position by the cooperation of the second positioning projections 164 with the securing projections 126.
In this fully inserted position, rail surfaces 123 of the connector position assurance device 130 is moved beneath a release lever 125 which is provided at the end of the latch 120 (as indicated by the lines shown in phantom in
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A terminal position assurance receiving recess 216 is provided in a respective side wall 212 of the second housing assembly 200. As shown in
As shown in
The first terminal engagement section 238 has an extension arm 242 and a terminal positioning surface 244 which is provided at the end of the extension arm 242. Location projections 246 are provided on the extension arm 242.
Two second terminal engagement arms 240 from either side of the base 232 of the terminal position assurance member 230. The second terminal engagement arms 240 have fixed ends 248 which are integrally attached to the base 232, free ends 250 which are spaced from the fixed ends 238 and mid sections 252 which extend between the fixed ends 248 and the free ends 250. Each of the second terminal engagement arms 240 have a first surface 254 and an oppositely facing second surface 256. A second surface 256 of a first of the second terminal engagement arms 240 faces the second surface 256 of a second of the second terminal engagement arms 240. The second terminal engagement arms 240 have first latching shoulders 260, second latching shoulders 262 and third latching shoulders 264 which are provided on the first surfaces 254.
Terminal locking projections 266 extend from the mid sections 252 of the second terminal engagement arms 240 to the first surfaces 234 of the base 232. The terminal locking projections 266 have terminal engagement surfaces 268 provided thereon. Each of the terminal locking projections 266 has a curved surface which faces the second surface 256 of an opposed second terminal engagement arm 240.
Referring to
With the connector 300 properly inserted into the conductor receiving passages 214, an operator forces the terminal position assurance member 230 to a second or inserted position, as shown in
In the second position, as shown in
If the connector 300 is not properly seated in the conductor receiving passage 214, the terminal position assurance member 230 is prevented from moving to the second position. If the connector 300 is not properly seated in the conductor receiving passage 214, the terminal engagement surfaces 268 of the terminal locking projections 266 of the terminal engagement arms 240 will engage the outer shell 332 of the connector 300 preventing the movement of the terminal position assurance member 230 to the second, fully inserted position. If the terminal position assurance member 230 is not properly positioned in the second position, the terminal position surface 244 of the first terminal engagement section 232 of the terminal position assurance member 230 will engage the mating end 102 of the first housing assembly 100, thereby preventing the first housing assembly 100 for being mated with the second housing assembly 200.
While the invention has been described with reference to a preferred embodiment, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the spirit and scope of the invention as defined in the accompanying claims. One skilled in the art will appreciate that the invention may be used with many modifications of structure, arrangement, proportions, sizes, materials and components and otherwise used in the practice of the invention, which are particularly adapted to specific environments and operative requirements without departing from the principles of the present invention. The presently disclosed embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being defined by the appended claims, and not limited to the foregoing description or embodiments.