The present invention generally relates to electrical contacts of electrical connectors, and in particular relates to gender-neutral electrical contacts.
Electrical connector assemblies include electrical connectors that can attach to provide signal connections between electronic devices. In particular, each electrical connector includes electrical signal contacts that are provided as male that receive complementary female contacts, or female contacts that are inserted into complementary male contacts. The gender-specific contacts can require specialized connectors that are configured to connect with a mating connector. Furthermore, the connectors need to be precisely aligned for connection.
Hermaphroditic, or gender-neutral, electrical connectors have been introduced that allow for general interchangeability between connectors of a connector assembly. Conventional gender-neutral electrical contacts extend out from a housing, and have an offset region, such that the offset regions of contacts to be mated are aligned. Thus, when the connectors are mated, the offset regions of the electrical cam over each other, thereby causing resistance to insertion, and requiring an insertion force in order to mate the connectors. Unfortunately, the insertion force increases as the connectors are brought toward each other to their fully mated positions, which can lead to significant wear of the contacts.
What is therefore desired is an electrical connector having gender-neutral contacts that reduce the insertion forces with respect to conventional electrical connectors.
In accordance with one aspect, an electrical connector includes a housing and at least one electrical contact supported by the housing. The electrical contact defines a contact body extending out from the housing, a mounting end disposed upstream of the contact body, and a mating end disposed downstream of the contact body. The mating end extends inward toward the housing such that the mating end is spaced from the contact body. The mating end defines mating surface having a concave region and a convex region disposed downstream of the concave region. The convex region defines a peak disposed between a pair of downsloped surfaces that extend toward the contact body in a direction outward from the peak.
One aspect of the invention is a connector system that requires less force to mate two mating connectors together. The geometry of the electrical contacts helps to gradually overcome frictional and normal forces of mating electrical contacts, as a function of mating distance, thereby decreasing the amount of externally applied mating force needed to press mating connectors closer to one another. Stated another way, when one starts to press two of the mating connectors together, less force is required to continue mating the two mating connectors. The decrease in external mating force continues until the mating connectors are fully mated.
Referring to
Certain directional terminology may be used in the following description for convenience only and should not be considered as limiting in any way. For instance, while the longitudinal and lateral directions are illustrated as extending along a horizontal plane, and that the transverse direction is illustrated as extending along a vertical plane, the planes that encompass the various directions may differ during use, depending, for instance, on the desired orientation of the electrical connector 20. Accordingly, the terms “vertical,” “horizontal,” and derivatives thereof are used to describe the connector 20 as illustrated merely for the purposes of clarity and convenience, it being appreciated that these orientations may change during use. Likewise, unless otherwise indicated, the terms “upper,” “lower,” “inner,” “outer,” and derivatives thereof designate directions along a given directional component toward and away from, respectively, the geometric center of the referenced object.
The connector 20 includes a connector housing 22 defining a mounting end 29 and a mating end 30. The connector housing 22 supports an electrical contact assembly 24 that includes a plurality of electrically conductive contacts 50 retained in the housing 22. Each contact has a first mounting end 52 disposed proximate to the mounting end 29 of the housing 22, and a second mating end 54 disposed proximate to the mating end 30 of the housing 22. The mounting end 29 of the housing is configured for attachment to a complementary electrical component, such as a printed circuit board 25. Thus, the mounting ends 52 of the contacts 50 are configured to connect to electrical traces on the circuit board 25.
Referring also to
In the illustrated embodiment, the connector assembly 32 is a vertical or mezzanine connector assembly, whereby the mating ends of the connectors 20 and 20′ are parallel to the mounting ends of the vertical or mezzanine connectors. Hence, the printed circuit boards 25 or other electrical components can be oriented parallel to each other. However, the connectors 20 and 20′ could be alternatively configured. For instance, in alternative embodiments, one or both of the electrical connector could be configured as a right-angle connector whereby the mounting end extends in a direction substantially perpendicular to the mating end. Thus, the electrical connectors 20 and 20′ and the electrical connector assembly 32 are not intended to be vertical or mezzanine, or right-angle unless otherwise indicated.
The first electrical connector 20 will now be further described with reference to
The electrical contact assembly 24 includes a receptacle portion 42 and a header portion 44. A first row 46 of longitudinally spaced electrical contacts 50A is disposed in the receptacle portion 42, and a second row 48 of longitudinally spaced electrical contacts 50B is disposed in the header portion 44. The electrical contact assembly 24 includes a base 45 that supports the electrical contacts 50 in any desired manner. For instance, the base 45 can be formed from a resin or other suitable dielectric material that is injection molded around the lower ends of the contacts 50 such that the mounting ends 52 are exposed and configured to mate with the printed circuit board 25. The contacts 50 extend up through vertical, and laterally elongate, slots 51 formed in the base 45.
The receptacle portion 42 of the contact assembly 24 is defined by the side wall 38, the end walls 39 and 40 and a longitudinal vertical divider wall 56 that extends between the end walls 39 and 40. The divider wall 56 separates the receptacle portion 42 from the header portion 44.
The header portion 44 is defined by a pair of inner end walls 58 and 60 that are inwardly displaced from the end walls 39 and 40, and the divider wall 56 that extends between the inner end walls 58 and 60. A plurality of dividers 62 extend laterally outward from the divider wall 56 into the header portion 44. The dividers 62 are vertically oriented, extend between the divider wall 56 and the side wall 36, and are longitudinally spaced from each other such that contact-receiving voids 64 are disposed between adjacent dividers 62. The contact-receiving voids 64 are vertically aligned with the slots 51 formed in the base 45. The electrical contacts 50A in the first row 46 are aligned with the electrical contacts 50B in the second row 48.
The longitudinal distance between the longitudinally outer surfaces of the end walls 58 and 60 is substantially equal to, or slightly less than, the longitudinal distance between the longitudinally inner surfaces of the end walls 39 and 40 at the receptacle portion 42. Furthermore, the lateral distance between the longitudinally outer surfaces of the divider wall 56 and the inner end walls 58 and 60 and dividers 62 of the header portion 44 is substantially equal to, or slightly less than, the lateral distance between the laterally inner surfaces of the side wall 38 and the divider wall 56 of the receptacle 42.
Accordingly, referring to
Furthermore, the lateral distance between the electrical contacts 50A of the first row 46 and the side wall 38 is less than the lateral distance between the electrical contacts 50B of the second row 48 and the side wall 36. Accordingly, when the connectors 20 and 20′ mate such that the side wall 38 is aligned with the side wall 40′, and the side wall 40 is aligned with the side wall 38′, the contacts 50A and 50B of the connectors are laterally offset from each other and can mate with each other in the manner described below.
It should be appreciated that when the connectors 20 and 20′ are mated, an insertion force is required to overcome the frictional forces generated by the housings 22 and 22′ during mating, as well as the frictional forces generated by the electrical contacts 50 and 50′during mating. As will now be described with reference to
Referring to
It should be further appreciated that all of the electrical contacts 50A are identically or substantially identically constructed, and all of the electrical contacts 50B are identically or substantially identically constructed. Accordingly, the description of the electrical contact 50A is applicable to all electrical contacts 50A and 50A′ unless otherwise indicated, and the description of the electrical contact 50B is applicable to all electrical contacts 50B and 50B′ unless otherwise indicated. Furthermore, because the electrical contacts 50A and 50B are identically or substantially identically constructed, except as to the configuration of the mounting ends 52A and 52B, the electrical contacts 50A and 50B are otherwise described with reference to like reference numbers identifying like structure. Therefore, a reference made to an electrical contact 50 and structure thereof applies equally to both electrical contacts 50A and 50B.
As illustrated, the electrical contact 50 is an electrical signal contact configured to transfer data between a signal contact of the complementary connector 20′ and the electrical component, such as the printed circuit board 25, though it should be appreciated that the contact 50 could alternatively be provided as a power contact unless otherwise indicated. In one embodiment, the electrical contact is made from any suitably electrically conductive material, such as a copper alloy. The contact can have thickness Th of 0.15 mm, though any thickness can be used depending upon the desired insertion force characteristics and normal force characteristics at the locations of contact of the complementary mated ends 54 and 54′. Each electrical contact 50 defines a contact body 76 that can define a round, for instance circular, cross section as illustrated, or can alternatively have a cross section that defines a square, rectangular, or any alternative suitable geometry. The contact 50 can be made from any suitable electrically conductive material, and can be sufficiently flexible such that the contact 50 can deflect or yield when being mated to the associated contact 50′.
The contact body 76 can define a vertical stem 78, and a bent portion 82 connected to the upper end of the stem 78. The bent portion 82 can be substantially “U” shaped so as to define a hairpin turn, and curves laterally outward and downward from the stem 78 so as to define a distal portion 85 disposed downstream of the bent portion 82. The distal portion 85 is thus laterally spaced from the stem 78. Accordingly, the stem 78 defines a proximal portion 79 of the contact 50 extending transversely outward from the base 45 of the housing 22 and laterally spaced from the distal portion 85 by a gap 65. The distal portion 85 extends transversely inward from the bent portion 82 toward the base 45 of the housing 22. The bent portion 82 separates the proximal portion 79 of the contact body 76 from the distal portion 85 of the contact body. The distal portion 85 defines the mating end 54 of the contact 50, and terminates at a free terminal end 87. The mounting end 52 is disposed proximal to or upstream of the contact body 76, and the mating end 54 is disposed distal to or downstream of the contact body 76.
The mating end 54 extends generally transversely inward (or down) toward the base 45 of the housing, and laterally outward away from the contact body 76 or stem 78. Because the mating end 54 has a transversely inward directional component and the body 76 or stem 78 has a transversely outward (or upward) component, it can be said that the bent portion 82 causes the mating end 54 to extend in an opposite direction with respect to the body 76 or stem 78. Furthermore, the mating end 54 is in at least partial lateral alignment with, or laterally overlaps, the contact body 76 or stem 78 such that a common axis that extends in a direction perpendicular to the contact body 76 or stem 78, for instance in the lateral direction, extends through both the mating end 54 and the body 76 or stem 78. The mating end 54 defines a laterally outer mating surface 55 configured to engage the mating surface 55′ of the complementary contact 50′, and an opposing inner surface 57 that faces the body 76 or stem 78.
The proximal and distal portions 79 and 85 of the contacts 50B are at least partially disposed in the contact-receiving voids 64 of the header portion 44 (see
In this regard, it should be appreciated that while the directional terms “laterally inward” and “laterally outward” and derivatives thereof used with reference to the distal portion 85 refer to a direction toward and away from the proximal portion 79, respectively, it should be further appreciated that these directional terms further refer to a direction along the mating surface 55 away from and towards, respectively, the complementary contact 50′ as the contacts 50 and 50′ are mated.
As used herein, the directional term “distal,” “downstream” and derivatives thereof are used to refer to directions along the contact 50 from the proximal portion 79 toward the distal portion distal portion 85. Thus, a distal direction of the proximal portion 79 extends generally upward in the illustrated orientation of the contact 50, and a distal direction of the distal portion 85 extends generally downward. The directional term “proximal,” “upstream”, and derivatives thereof refers to a direction along the contact 50 opposite that of the distal or downstream direction.
The stem 78 extends down from the bent portion 82, and connects to a base portion 80 that extends laterally outward from the lower end of the stem 78, and defines the mounting end 52 of the contact 50. In particular, the base portion 80A of the contact 50A extends laterally out from the stem 78 in a direction opposite the direction that the distal portion 85 is offset from the proximal portion 79. Thus, the base portion 80A extends in a direction toward the side wall 38 of the connector housing 22 (see
With continuing reference to
It should be appreciated that one or both of the transverse outer ends of a convex or concave region can define a transverse outer end of an adjacent concave or convex region, respectively. The transitions between the adjacent concave and convex regions, and the transitions between transverse outer ends and the transverse inner ends of the concave and convex regions can define a smooth and constant radius of curvature, though it should be appreciated that the transitions could be defined by any suitable shape as desired, including angles as opposed to curved surfaces. Accordingly, reference to convex, concave, and curved surfaces or regions should not be construed as being limited to curvatures.
As will now be described with continuing reference to
In particular, the bent portion 82 extends distally from the stem 78 along a radius of curvature, and extends greater than 180° from the stem 78, thereby providing the proximal convex region 93. The proximal convex region 93 includes a peak 97 that defines first contact location as a pair of contacts 50 and 50′ are mated. Thus, the convex region 93 defines an upsloped surface 63 disposed between the bent portion 82 and the peak 97. The upsloped surface 63 is configured to provide an insertion force as the contacts 50 and 50′ are mated relative to the insertion force provided by the downsloped surface 59, thereby providing tactile feedback during insertion. The bent portion 82, and thus the convex region 93, can be defined by any radius of curvature as desired, such as between 0.1 mm and 0.6 mm, or more preferably between 0.3 mm and 0.4 mm. In one embodiment, the radius of curvature of the bent portion 82 is approximately 0.35 mm.
The concave region 88 extends distally from the convex region 93. In the illustrated embodiment, the convex region 93 transitions directly into the concave region 88. The convex region 88 defines a valley 89, such that a downsloped surface 59 is disposed between the peak 97 of the convex region 93 and the valley 89. While the downsloped surface 59 extends laterally inward as illustrated, it should be further appreciated that a downsloped surface can be more broadly described as flaring laterally outward less than the surface proximal to the downsloped surface, which is the convex region 93 as illustrated with respect to the downsloped surface 59.
The concave region 88 can be defined by any radius of curvature as desired, such as between 0.5 mm and 0.4 mm, or more preferably between 1 mm and 3 mm. In one embodiment, the radius of curvature of the bent portion 82 is approximately 2 mm. Furthermore, in one embodiment, the concave region 88 defines a lateral distance that is between 300% and 500% with respect to the lateral distance defined by the proximal convex region 93, though any relative lateral distance of the concave region and the convex region 93 is contemplated. As will be described in more detail below, the concave region 88 is thus configured to produce a variable insertion forces as contacts 50 and 50′ are mated.
The distal convex region 98 extends distally from the concave region 88. In the illustrated embodiment, the concave region transitions direction into the convex region 98. As will be appreciated from the description below, the convex region 98 defines a peak 99 that is laterally outwardly displaced with respect to the peak 97 of the convex region 93. second contact location as a pair of contacts 50 and 50′ are mated. The concave region 88 defines a downsloped distal end 92 that flares laterally inward toward the stem 78 at a rate greater than that of the downsloped surface 59 of the concave region 88 in the illustrated embodiment, and terminates at the free terminal end 87. In an alternative embodiment, the terminal end 87 could connect to the vertical stem 78. The distal end 92 of the distal convex region 98 further defines the distal end of the concave portion 85 of the contact 50, and thus also defines the distal end of the contact 50. The distal concave region 98 can be defined by a radius of curvature substantially equal to that of the proximal convex region. Thus, the convex regions 93 and 98 change directions, or curve, at a greater rate than the concave region 88. Otherwise stated, the concave region 88 has a curvature that is shallower than that of the convex regions 93 and 98.
It should be appreciated that the convex region 88 further defines an upsloped surface 61 disposed between the valley 89 and the peak 99 of the distal convex region 98. While the upsloped surface 61 extends laterally outward as illustrated, it should be further appreciated that the downsloped surface can be more broadly described as flaring laterally inward less than the upstream surface, which is the downsloped surface 59 as illustrated. Thus, as described below, the upsloped surface 59 is configured to increase the insertion force as the contacts 50 and 50′ are mated relative to the insertion force provided by the downsloped surface 59, thereby providing tactile feedback during insertion.
In the illustrated embodiment, the proximal convex region 93 is disposed immediately adjacent the concave region 88 such that the distal surface of the convex region 93 that is recessed with respect to the peak 97 also defines the downsloped surface 59. Likewise, the concave region 88 is disposed immediately adjacent the distal convex region 98. Accordingly, the peak 93 of the proximal convex region 93 is disposed between a pair of surfaces, namely the downsloped surface 59 and the bent portion 82, that slope inward from the peak 93 toward the stem 78 in opposing outward directions from the peak 93 along the mating end 54. The valley 89 of the concave region 88 is disposed between a pair of surfaces, namely the downsloped surface 59 and the upsloped surface 61, that slope outward from the valley 89 away from the stem 78 in opposing outward directions from the valley 89 along the mating end 54. Furthermore, the peak 99 of the distal convex region 98 is disposed between a pair of surfaces, namely the upsloped surface 61 and the downsloped surface 92, that slope inward from the 99 toward the stem 78 in opposing outward directions from the peak 99 along the mating end 54. It should be appreciated, however, that other structure at the distal portion could separate the proximal convex region 93 from the concave region 88, and the concave region 88 from the distal convex region 98, unless otherwise indicated. Accordingly, the regions 93, 88, and 98 can be said to be disposed adjacent to each other to indicate a spatial relationship without being limited to being disposed immediately adjacent each other, unless otherwise indicated. Additionally, the convex portion 85 can include additional convex and concave regions as desired.
The mating of the electrical contacts 50 and 50′ will now be described with reference to
With initial reference to
As illustrated, the contacts 50B and 50A′ are laterally offset with respect to each other such that the mating ends 54 and 54′ of the distal portions 85 and 85′ are aligned. In particular, the proximal convex regions 93 are aligned. It should be appreciated that in the illustrated embodiment, the contacts 50B and 50A′ are mated by applying an external insertion force, or “insertion force” as used herein, that is required to cause the contacts to move transversely inward relative to each other. Hence both connectors 20 and 20′ can be brought toward each other, or one of the connectors can be brought toward the other, while the other remains stationary. For the purposes of clarity, the process of mating will be described with respect to an embodiment whereby the connectors 20 and 20′, and thus the contacts 50B and 50A′, are moved toward each other in the transverse or vertical direction, it being appreciated that the actual direction of contact insertion during use will be dependent, for instance, on the orientation of the connectors 20 and 20′.
Accordingly, as the contacts 50B and 50A′ begin to mate from the initial position illustrated in
The applied increasing insertion force that causes the peaks 97 and 97′ to ride along the upsloped surfaces 63′ and 63 provides tactile feedback that the contacts 50B and 50A′ are being mated. For instance, referring to
Furthermore, the contacts 50B and 50A′ flex laterally outward away from each other as the proximal convex regions 93 and 93′ ride along each other. It should be appreciated that both the distal portions 85 and 85′ and the proximal portions 79 and 79′ of each contact 50B and 50A′ deflect or yield away from the opposing contact as the contacts 50B and 50A′ are mated. Accordingly, the contacts 50B and 50A′ apply a spring force toward each other. Because the upsloped surfaces 63 and 63′ flare laterally outward, the spring force biases the contacts 50 and 50′ transversely away from each other as the upsloped surfaces 63 and 63′ ride along each other until the peaks 97 and 97′ are aligned. The biasing force is overcome by the insertion force as the contacts 50B and 50A′ are moved from the initial position to the first intermediate mating position illustrated in
As the contacts 50B and 50A′ continue to mate from the first intermediate mating position illustrated in
It should be appreciated that, unless otherwise indicated, a reduction of insertion force is intended to encompass both a reduction of the rate of insertion force increase and reduction in insertion force level, including a reversal in insertion force such that no external insertion force is necessary to further mate the contacts 50B and 50A′. Referring to
Notably, once the peaks 97 and 97′ engage the complementary downsloped surfaces 59′ and 59 with continued insertion, the contacts 50B and 50A′ will not be subject to detachment unless a separation force is applied that is sufficient to cause the peaks 97 and 97′ to ride back over the downsloped surfaces 59′ and 59, which would present upsloped surfaces with respect to separation. Thus, the contacts 50B and 50A′ are not likely to become inadvertently separated from each other. Accordingly, it can be said that a first contact location provided by the peaks 97 and 97′ and the complementary downsloped surfaces 59′ and 59 has been mated when the contacts 50B and 50A′ have moved to the second intermediate mating position illustrated in
As the contacts 50B and 50A′ continue to mate from the second intermediate mating position illustrated in
Notably, once the peaks 97 and 97′ engage the complementary upsloped surfaces 61′ and 61 with continued insertion, the contacts 50B and 50A′ become engaged at two contact locations. In particular, the first contact location is provided by the peak 97 and the complementary distal convex region 98′, and the second contact location is provided by the peak 97′ and the complementary distal convex region 98. It should be appreciated that the contacts 50B and 50A′ provide a second increase of insertion force that provides tactile feedback that the pair of contact locations are being mated, as illustrated in
As the contacts 50B and 50A′ continue to mate from the third intermediate mating position illustrated in
As the contacts 50B and 50A′ continue to mate from the third intermediate mating position illustrated in
As the contacts 50B and 50A′ continue to mate from the fourth intermediate position illustrated in
Notably, once the peaks 99 and 99′ the first and second contact locations will not be subject to detachment unless a separation force is applied that is sufficient to cause the peaks 99 and 99′ to ride back over the downsloped surfaces 59′ and 59, which would present upsloped surfaces with respect to separation. Thus, the contacts 50B and 50A′ are not likely to become inadvertently separated from each other. Accordingly, it can be said that a first contact location defined by the peak 99 and the complementary concave region 88′, and a second contact location is defined by the peak 99′ and the complementary concave region 88 have been fully mated.
Referring to
As illustrated in
It should be appreciated that when mating the contacts 50B and 50A′ from the initial aligned position to the fully mated position, a first increase of insertion force provides tactile feedback when a first contact location begins to mate. A first reduction of insertion force provides tactile feedback when the first contact location is mated. A second increase of insertion force provides tactile feedback when a second contact location begins to mate, and a second reduction of insertion force provides tactile feedback when the first and second contact locations are fully mated.
In this regard, it should be appreciated that two separate and spaced contact locations of the contacts 50B and 50A′ ride along the downsloped surfaces 59′ and 59 when the contacts 50B and 50A′ are mated. It should be further appreciated that the contacts 50B and 50A′ define a wiping distance along the respective distal portions 85 and 85′ between the proximal convex regions 93 and 93′ and the peaks 99 and 99′ of the distal convex regions 98 and 98′, respectively. Furthermore, the distance between the peaks 97 and 99 is not greater than the total wiping distance of the mating surface 55. In the illustrated embodiment, the contacts 50B and 50A′ begin to mate at a location upstream of the peaks 97 and 97′, and as a result, the distance between the peaks 97 and 99 is less that the total wiping distance.
With continuing reference to
As a result, the insertion force to mate the contacts 50 and 50′ is reduced with respect to an insertion force required to mate a similarly constructed contact whose effective length is equal to the height of the contact 50, because the similarly constructed contact would undergo the same amount of cumulative flexing, but the flexing would occur over a shorter effective length than the contact 50, which would increase the insertion forces. As a result, the contact 50 can be configured with a low vertical profile without significantly increasing the insertion forces by providing an effective length that is greater than the height of the contact, thereby. In the illustrated embodiment, the height H of the contact 50 is less than 5 mm, and substantially equal to 4 mm.
The embodiments described in connection with the present invention have been presented by way of illustration, and the present invention is therefore not intended to be limited to the disclosed embodiments. Accordingly, those skilled in the art will realize that the invention is intended to encompass all modifications and alternative arrangements included within the spirit and scope of the invention, as set forth by the appended claims.
This application claims priority to U.S. Patent Application Ser. No. 61/142,003, filed Dec. 31, 2008, the disclosure of which is hereby incorporated by reference as if set forth in its entirety herein. This disclosure is related to U.S. patent application Ser. No. 12/237,756 filed Sep. 25, 2008, the disclosure of which is hereby incorporated by reference as if set forth in its entirety herein.
Number | Date | Country | |
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61142003 | Dec 2008 | US |