Patent Grant
8147272
The subject matter described herein relates generally to electrical connectors, and more particularly, to shielded header connectors.
Transmissions in some automobiles may include a transmission case that has wires extending from the case or a connector joined to the case. The wires may be coupled with other components or the connector may be joined with another connector in the automobile to transfer current to the transmission. The current may be used to shift or change gears in the transmission, or operate a pump of the transmission, for example.
The wires or connectors exit from the transmission case from openings in the case. These openings may need to be sealed in order to prevent contaminants from outside of the transmission case, such as moisture, dirt, and the like, from entering into the transmission case via the openings. Additionally, the openings may need to be sealed to prevent contaminants inside the transmission case, such as transmission fluid, from exiting the transmission case via the openings.
Hybrid and electric automobiles may use relatively high voltage current to power various components in the automobiles, including transmissions. In order to transfer high voltage current to the transmissions in the hybrid or electric automobiles, a shielded connector may be needed. For example, rather than using unshielded wires or connectors to transfer power to the transmissions, a shielded connector may be needed in order to restrict emission of electromagnetic interference from the connector. The addition of an electromagnetic shield to the connector may require a connector housing that is formed of multiple sections or nested portions with a conductive body between the sections or portions. But, providing a connector with multiple sections or portions introduces several interfaces between the sections or portions into the connector. These interfaces may provide pathways for contaminants, such as moisture and transmission fluid, to pass into the interior of the connector. Contaminants that ingress into the connector may short out or otherwise interfere with transfer of the high voltage current through the connector, or may result in transmission fluid in the transmission case leaking out of the transmission case.
A need exists for a header connector having sealing that restricts ingress of contaminants into the connector and/or the passage of contaminants through the connector.
In one embodiment, a header connector assembly is provided. The header connector assembly includes an outer housing, an inner housing, a shield subassembly, and a seal body. The outer housing is disposed in an opening of a panel and includes a cavity. The inner housing includes a channel and is disposed in the opening of the panel. The inner housing is received in the cavity of the outer housing and includes a channel configured to have a contact disposed therein. The shield subassembly is disposed between the outer housing and the inner housing. The shield subassembly engages the panel to electrically couple the shield subassembly with the panel. The seal body is disposed between the panel and at least one of the outer housing and the inner housing. The seal body restricts passage of contaminants between the panel and at least one of the outer housing and the inner housing.
In another embodiment, another header connector assembly is provided. The header connector assembly includes a housing subassembly, an electromagnetic shield subassembly, a forward seal body, and a rear seal body. The housing subassembly has a high voltage contact that is configured to engage a conductive member of a connector that mates with the housing subassembly. The shield subassembly is disposed in the housing subassembly and engages a panel to electrically couple the shield subassembly with the panel. The forward seal body is disposed between the shield subassembly and a front side of the panel. The rear seal body is disposed between the shield subassembly and a rear side of the panel. The forward and rear seal bodies seal interfaces between the housing subassembly and the panel on opposite sides of the shield subassembly.
In another embodiment, another header connector assembly is provided. The header connector assembly includes a housing subassembly, a contact, an outer conductive shield, an inner conductive shield, and a seal body. The housing subassembly is disposed in an opening of a panel and includes a channel. The contact is disposed in the channel of the housing subassembly and is configured to engage a conductive member of a connector that mates with the housing subassembly. The outer conductive shield is joined to the housing subassembly and engages the panel along a perimeter of the housing subassembly. The outer conductive shield includes an opening extending therethrough. The inner conductive shield extends through the opening in the outer conductive shield and is electrically coupled with the outer conductive shield. The inner conductive shield defines an interior chamber with the channel of the housing subassembly disposed therein. The seal body is disposed between the panel and the housing subassembly. The seal body restricts passage of contaminants between the panel and the housing subassembly.
The header connector assembly 100 mates with a connector 800 (shown in
In one embodiment, the panel 102 is a portion of a transmission case in a vehicle, such as a hybrid or electric automobile. The panel 102 may be an exterior surface of the transmission case such that the front side 106 of the panel 102 is exposed to environmental contaminants such as moisture, dirt, and the like while the back side 108 is exposed to internal contaminants such as transmission fluid. The panel 102 may, however, be a portion of a different surface. For example, the panel 102 may represent the exterior surface of an electrical component or other device that communicates power and/or data signals via the header connector assembly 100. The panel 102 has a thickness 112 between the opposite sides 106, 108. In the illustrated embodiment, a flange 114, 118 protrudes from each of the sides 106, 108 of the panel 102 with the opening 104 extending through the panel 102 and encircled by the flanges 114, 118. The portion of the panel 102 that is located within the opening 104 and encircles the header connector assembly 100 in the opening 104 may be referred to as a compression surface 116 of the panel 102. As described below, seal bodies 326, 328 (shown in
The header connector assembly 100 may be referred to as a pass-through connector or header connector because the header connector assembly 100 provides a conductive pathway between a connector 800 (shown in
In order for the shield subassembly 318 (shown in
The header connector assembly 100 includes a housing subassembly 312. In the illustrated embodiment, the housing subassembly 312 includes an inner housing 314 that is joined to an outer housing 316. While the inner and outer housings 314, 316 are shown and described herein as separate bodies, alternatively, the inner and outer housings 314, 316 may be formed as a single, unitary body. As described below, the inner housing 314 extends into the outer housing 316 and the contacts 302 are disposed within the inner housing 314. The inner and outer housings 314, 316 are described in more detail below in connection with
The shield subassembly 318 includes an outer conductive shield 320 joined with an inner conductive shield 322. While the outer and inner conductive shields 320, 322 are shown and described herein as separate bodies, alternatively, the outer and inner conductive shields 320, 322 may be formed as a single, unitary body. As described below, the outer conductive shield 320 engages the panel 102 (shown in
The header connector assembly 100 shown in
A back portion 404 of the outer housing 316 extends from the forward portion 402 to the interface end 400. The back portion 404 has an approximate cylindrical or tubular shape in order to fit within the approximately circular opening 104 (shown in
In the illustrated embodiment, the back portion 404 includes recesses 420 disposed along the outer periphery of the back portion 404 at the interface end 400. The recesses 420 receive retention fingers 502 (shown in
The inner housing 314 has an elongated body that extends from a front end 422 to the back end 112. The inner housing 314 includes a forward portion 410 joined to a back portion 412. The forward portion 410 extends from the front end 422 to an interface end 416. The back portion 412 extends from the interface end 416 to the back end 112. A channel 414 extends through the inner housing 314 from the front end 422 to the back end 112. The contacts 302 (shown in
The inner housing 314 is joined with the outer housing 316 such that the forward portion 410 of the inner housing 314 extends into the cavity 408 in the forward portion 402 of the outer housing 316. As described below, the outer conductive shield 320 is disposed between the interface end 416 of the inner housing 314 and the interface end 400 of the outer housing 316. The inner conductive shield 322 partially encloses the forward portion 410 of the inner housing 314 and is disposed between the forward portion 410 of the inner housing 314 and the outer housing 316 inside the cavity 408 of the outer housing 316.
A groove 418 extends around an outer perimeter of the inner housing 314 in the back portion 412. The rear seal body 328 (shown in
The outer conductive shield 320 includes cantilevered beams 500 that protrude from one side of the outer conductive shield 320 from the perimeter of the opening 324 in the outer conductive shield 320. Alternatively, the beams 500 may not be cantilevered and/or the beams 500 may extend from a different side of the outer conductive shield 320. The beams 500 engage the inner conductive shield 322 when the inner conductive shield 322 is inserted through the opening 324. The beams 500 engage the inner conductive shield 322 to electrically couple the outer and inner conductive shields 320, 322. For example, when the inner conductive shield 322 is placed into the opening 324, the beams 500 may be biased outward and away from the opening 324 by the inner conductive shield 322. The outwardly biased beams 500 may then apply a force on the inner conductive shield 322 that maintains contact between the beams 500 and the inner conductive shield 322.
In the illustrated embodiment, the outer conductive shield 320 includes the retention fingers 502 and the spring fingers 504 around the periphery of the outer conductive shield 320. The retention fingers 502 are extensions or cantilevered beams of the outer conductive shield 320 that secure the outer conductive shield 320 to the outer housing 316 (shown in
The spring fingers 504 are extensions of the outer conductive shield 320 that engage the panel 102 (shown in
The inner conductive shield 322 has an elongated body that extends between opposite ends 506, 508. The inner conductive shield 322 has a shape that compliments or corresponds to the shape of the forward portion 410 (shown in
The inner and outer conductive shields 322, 320 are disposed at interfaces between and separate the inner and outer housings 314, 316 from one another. For example, the inner conductive shield 322 and the forward portion 410 of the inner housing 314 may be loaded into the cavity 408 of the outer housing 316 through the opening 324 in the outer conductive shield 320. In one embodiment, the inner conductive shield 322 and inner housing 314 are loaded into the outer housing 316 until the interface end 416 of the inner housing 314 engages the outer conductive shield 320. For example, the outer conductive shield 320 may be sandwiched between the interface end 400 of the outer housing 316 and the interface end 416 of the inner housing 314. In such a position, the outer conductive shield 320 separates and is disposed at an interface between the outer and inner housings 316, 314. The inner conductive shield 322 is located within the outer housing 316 and separates the outer housing 316 from the inner housing 314 within the outer housing 316.
The contact subassembly 300 (shown in
In use, electromagnetic interference (EMI) emanates from or is generated by current flowing through the contacts 302. The inner conductive shield 322 surrounds the contacts 302 to provide EMI shielding around the contacts 302. EMI radiating from the contacts 302 is shielded from exiting the header connector assembly 100 by the inner conductive shield 322. The outer conductive shield 320 is electrically coupled to the inner conductive shield 322 such that the EMI from the contacts 302 is transferred from the inner conductive shield 322 to the outer conductive shield 320. The outer conductive shield 320 may engage the compression surface 116 (shown in
The forward and rear seal bodies 326, 328 assist in restricting transmission of contaminants, such as moisture or transmission fluid, into the header connector assembly 100 or through the opening 104 in the panel 102 from one side 106, 108 to the other side 106, 108 of the panel 102. The forward and rear seal bodies 326, 328 are located on opposite sides of the outer conductive shield 320 to prevent ingress of contaminants from both sides 106, 108 of the panel 102 from passing into the header connector assembly 100 along the outer conductive shield 320 and/or the inner conductive shield 322.
The forward seal body 326 may be compressed between the outer housing 316 and the compression surface 116 of the panel 102 to seal an interface between the header connector assembly 100 and the panel 102. This seal restricts ingress of contaminants coming from the front side 106 of the panel 102 from passing through the interface between the outer housing 316 and the panel 102 and into the interface between the outer housing 316 and the inner housing 314. For example, the forward seal body 326 may prevent moisture from outside of a transmission case from passing into the interior of the header connector assembly 100 via the interfaces between the outer housing 316 and the panel 102 and between the interface ends 400, 416 of the outer and inner housings 316, 314.
The rear seal body 328 may be compressed between the outer housing 316 and the compression surface 116 of the panel 102 to seal an interface between the header connector assembly 100 and the panel 102. This seal restricts ingress of contaminants coming from the rear side 108 of the panel 102 from passing through the interface between the inner housing 314 and the panel 102 and into the interface between the outer housing 316 and the inner housing 314. For example, the forward seal body 326 may prevent transmission fluid from passing into the interior of the header connector assembly 100 via the interfaces between the inner housing 314 and the panel 102 and between the interface ends 400, 416 of the outer and inner housings 316, 314.
The forward and rear seal bodies 326, 328 are shown and described herein as separate bodies. Alternatively, the forward and rear seal bodies 326, 328 may be formed as a single, unitary body. For example, a single seal body may be disposed in each of the grooves 406, 418 (shown in
The outer conductive shield 320 engages the compression surface 116 of the panel 102 between the forward and rear seal bodies 326, 328 such that the forward seal body 326 seals an interface between the outer conductive shield 320 and the front side 106 of the panel 102 while the rear seal body 328 seals an interface between the outer conductive shield 320 and the rear side 108 of the panel 102. The inner conductive shield 322 encloses the contacts 302 and may engage a conductive shield 802 of the connector 800 to restrict emission of electromagnetic interference from the contacts 302 or conductive members 804 of the connector 800. For example, the electromagnetic interference emanating from or generated by the contacts 302 or conductive members 804 may be transferred to the panel 102 by the inner and outer conductive shields 322, 320.
Dimensions, types of materials, orientations of the various components, and the number and positions of the various components described herein are intended to define parameters of certain embodiments, and are by no means limiting and are merely exemplary embodiments. Many other embodiments and modifications within the spirit and scope of the claims will be apparent to those of skill in the art upon reviewing the above description. The scope of the invention should, therefore, be determined with reference to the appended claims, along with the full scope of equivalents to which such claims are entitled. In the appended claims, the terms “including” and “in which” are used as the plain-English equivalents of the respective terms “comprising” and “wherein.” Moreover, in the following claims, the terms “first,” “second,” and “third,” etc. are used merely as labels, and are not intended to impose numerical requirements on their objects. Further, the limitations of the following claims are not written in means-plus-function format and are not intended to be interpreted based on 35 U.S.C. §112, sixth paragraph, unless and until such claim limitations expressly use the phrase “means for” followed by a statement of function void of further structure.
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