The subject matter herein relates generally to header assemblies.
Radio frequency (RF) coaxial connector assemblies have been used for numerous automotive applications, such as global positioning systems (GPS), car radios, mobile phones, air bag systems, and multimedia devices. Some coaxial connector assemblies are cable assemblies that are terminated to ends of coaxial cables. Coaxial cables typically consist of an outer conductor, an inner conductor, a dielectric, and a jacket or outer insulation. The outer conductor and the inner conductor of the cable electrically interface with corresponding inner and outer contacts of the connector, which may be a male or a female connector. Other coaxial connector assemblies are terminated to a circuit board rather than a cable. To interface with coaxial cable assemblies, such board-mounted assemblies include a coaxial interface defined by a center contact and an outer contact surrounding the center contact. Both the center and outer contacts terminate to the circuit board.
In order to standardize various types of connectors and thereby avoid confusion, certain industry standards have been established. One of these standards is referred to as FAKRA. FAKRA is the Automotive Standards Committee in the German Institute for Standardization, representing international standardization interests in the automotive field. The FAKRA standard provides a system, based on keying and color coding, for proper connector attachment. The keying and color identifying features of a FAKRA connector are typically on a housing. Male keying features can only be connected to like female keyways in FAKRA connector assemblies. Secure positioning and locking of connector housings is facilitated by way of a FAKRA defined catch on the male housing and a cooperating latch on the female housing.
Typical product families of FAKRA connectors include die-cast parts. For example, a header connector may include a die-cast shield component that includes an integral cylindrical outer contact which surrounds a center conductor to provide shielding and a grounding path. The die-cast shield component also may include a housing structure that mounts to a circuit board in order to provide electrical grounding and/or structural support for the header connector. Such known header connectors are not without disadvantages, however, as die-casting the shield component and/or other parts can be expensive and time-inefficient. An alternative to die-casting is stamping and forming one or more shield components out of a conductive panel, which may be more cost efficient than die-casting. However, stamped and formed shield components are generally not as strong structurally as die-cast parts, so stamping and forming the shield components of known FAKRA connector systems may result the in the components deforming (for example, bending) and/or breaking in response to mating and un-mating forces applied on the components. A need remains for a header assembly with shield components that are more cost efficient than die-cast parts and provide greater structural strength and resiliency than known stamped and formed parts.
In an embodiment, a header assembly is provided that includes a housing, an outer contact, and a center contact. The housing is composed of a dielectric material. The housing has a front panel including a front side and a rear side. The front panel defines a contact opening therethrough between the front side and the rear side. The housing also includes a base panel extending from the rear side of the front panel. The base panel is configured to mount to a circuit board. The outer contact is formed of an electrically conductive material. The outer contact includes a mating segment and a mounting segment. The mating segment extends through the contact opening of the front panel and defines a cylindrically-shaped channel. The mounting segment engages the base panel and is disposed between the base panel and the circuit board. The mounting segment is configured to mechanically couple and electrically terminate to the circuit board. The center contact is disposed in the channel of the outer contact.
In another embodiment, a header assembly is provided that includes a housing, an outer contact, and a center contact. The housing is composed of a dielectric material. The housing has a front panel including a front side and a rear side. The front panel defines a contact opening therethrough between the front side and the rear side. The housing also includes a base panel extending from the rear side of the front panel. The base panel defines a tunnel that extends rearward from a front of the base panel at the front panel. The base panel is configured to mount to a circuit board. The outer contact is formed of an electrically conductive material. The outer contact includes a mating segment and a mounting segment. The mating segment extends through the contact opening of the front panel and defines a cylindrically-shaped channel. The mounting segment is disposed within the tunnel of the base panel between an inner surface of the tunnel and the circuit board. The mounting segment is configured to mechanically couple and electrically terminate to the circuit board. The center contact is disposed in the channel of the outer contact.
In yet another embodiment, a header assembly is provided that includes a housing, a nose cone, and an outer contact. The housing is composed of a dielectric material. The housing has a front panel including a front side and a rear side. The front panel defines a contact opening therethrough between the front side and the rear side. The housing also includes a base panel extending from the rear side of the front panel. The base panel is configured to mount to a circuit board. The nose cone is coupled to the front panel and extends frontward from the front side of the front panel along a mating axis. The nose cone defines a cavity that aligns with and is open to the contact opening. The nose cone defines a mating interface for receiving a mating connector within the cavity in a loading direction along the mating axis. The nose cone has at least one keying rib along an exterior thereof. The outer contact is formed of an electrically conductive material. The outer contact extends longitudinally from a mating segment to a mounting segment. The mating segment is disposed within the cavity of the nose cone and extends through the contact opening of the front panel. The mounting segment is disposed rearward of the front panel and is located between the base panel and the circuit board. The mounting segment is configured to mechanically couple and electrically terminate to the circuit board.
One or more embodiments described herein are directed to a coaxial header assembly configured to be mounted to a circuit board. The header assembly is configured for electrically connecting a mating electrical connector to the circuit board. The header assembly may be a FAKRA-style connector assembly. The header assembly may include a stamped and formed outer contact that electrically terminates to the circuit board. The header assembly also includes a housing that engages and supports the outer contact in order to provide structural support for the outer contact to resist deformation and/or breaking due to mating and un-mating forces applied on the outer contact. The header assembly may avoid using at least some of the die-cast components installed in known header connectors. Optionally, the header assembly does not include any die-case components. Since die-casting may be more expensive than other manufacturing processes, such as stamping and forming, the header assembly may be more cost efficient than at least some known header connectors that incorporate die-cast components.
The circuit board 104 on which the header assembly 102 is mounted may form part of a communication system, such as for an automotive vehicle. For example, the communication system may be used in an automotive application, such as a global positioning system (GPS), car radio, mobile phone, rear-view camera, air bag system, multimedia device system, and the like. The communication system may have use in other types of applications such as aeronautic applications, marine applications, military applications, industrial applications, and the like. The circuit board 104 may form part of an antenna. The circuit board 104 may form part of a radio frequency (RF) system.
In the illustrated embodiment, the header assembly 102 constitutes a male assembly that is configured to be mated with a corresponding female mating connector (not shown). In an embodiment, the header assembly 102 is a standardized connector, such as a FAKRA standardized connector. The header assembly 102 has features designed according to desired FAKRA specifications. For example, the header assembly 102 may have certain keying configurations for restricting the mate-ability of the header assembly 102 to one or more specific mating connectors. In an alternative embodiment, the header assembly 102 may constitute a female assembly that is configured to be mated to a corresponding male mating connector.
Optionally, the header assembly 102 includes an electromagnetic interference (EMI) shield 124. The EMI shield 124 may be used to provide shielding at the window 108 (shown in
The header assembly 102 is oriented with respect to a vertical or elevation axis 191, a lateral axis 192, and a longitudinal or mating axis 193. The axes 191-193 are mutually perpendicular. Although the elevation axis 191 appears to extend generally parallel to gravity, it is understood that the axes 191-193 are not required to have any particular orientation with respect to gravity. The mating connector is configured to be mated to the mating end 110 of the header assembly 102 by moving the mating connector towards the header assembly 102 in a loading direction that is parallel to the mating axis 193.
The header assembly 102 may have any number of center contacts 128, outer contacts 126, and nose cones 130 that are held by the housing 114. For example, the housing 114 extends a width along the lateral axis 192. The header assembly 102 may include multiple nose cones 130 disposed side-by-side along the width of the housing 114. The header assembly 102 also includes multiple sets 132 of outer contacts 126 and center contacts 128 (shown in
The housing 114 includes a front panel 134 and a base panel 136. The front panel 134 has a front side 138 and a rear side 140. The base panel 136 extends from the rear side 140 of the front panel 134. The base panel 136 is angled relative to the front panel 134 and defines a top side 142 and an opposite bottom side 144. The base panel 136 defines at least a portion of the mounting end 112 of the header assembly 102. For example, the bottom side 144 faces the circuit board 104 (shown in
The nose cones 130 are coupled to the front panel 134 and extend from the front side 138 of the front panel 134. The nose cones 130 extend from the front panel 134 parallel to the mating axis 193. Each nose cone 130 defines a mating interface 148 for engaging a mating connector. For example, a portion of the mating connector may be received within a corresponding nose cone 130 and/or may engage and at least partially surround an exterior surface of the nose cone 130 at the mating interface 148. Optionally, each of the nose cones 130 may engage a different portion of a single mating connector, or at least some of the nose cones 130 of the header assembly 102 may be configured to engage different mating connectors. For example, the header assembly 102 shown in
In an embodiment, the mating end 110 of the header assembly 102 may define a FAKRA compliant connector such that the mating interfaces 148 of the nose cones 130 are keyed according to FAKRA specifications. For example, the nose cones 130 include keying ribs 150 on exterior surfaces thereof. The size, shape, and/or orientation of the keying ribs 150 may be used to define the different FAKRA interfaces 148. For example, the four nose cones 130 shown in
The outer contact 126 is composed of at least one electrically conductive material, such as copper, silver, aluminum, a combination of metals including at least one of copper, silver, and aluminum, and/or the like. The outer contact 126 is electrically conductive, and may be used to provide an electrical signal path, such as for grounding or transmitting signals. In an embodiment, the outer contact 126 is manufactured by stamping and forming a sheet of metal into a desired shape. In an alternative embodiment, the outer contact 126 may be formed via another process, such as die-casting or another molding process. The outer contact 126 extends longitudinally and includes a mating segment 156 and a mounting segment 158. The mating segment 156 is disposed adjacent to the mounting segment 158 along the length of the outer contact 126. The mating segment 156 and the mounting segment 158 may together define the entire length of the outer contact 126. The mating segment 156 has a closed cylindrical shape and defines a cylindrically-shaped channel 160. The mounting segment 158 has an open cylindrical shape in the illustrated embodiment. The mating segment 156 and the mounting segment 158 may be formed integral to one another, such as during a common stamping and forming process.
Referring now back to
The dielectric insert 152 is composed of a dielectric material, such as one or more plastics. The dielectric insert 152 extends longitudinally and defines an opening 166 extending the length of the insert 152 between a front end 168 and a rear end 170 thereof. The center contact 128 is received within the opening 166 of the dielectric insert 152 when the contact subassembly 154 is assembled. The dielectric insert 152 is configured to be received within the channel 160 of the outer contact 126 during the assembly of the contact subassembly 154. The dielectric insert 152 may include interference (or crush) ribs 172 along an exterior surface thereof for engaging an interior surface of the outer contact 126 that defines the channel 160. The interference ribs 172 are configured to increase friction between the dielectric insert 152 and the outer contact 126 to increase the force required to move the dielectric insert 152 relative to the outer contact 126. Therefore, when the contact subassembly 154 is assembled, the dielectric insert 152 surrounds the center contact 128 and is surrounded by the outer contact 126. The dielectric insert 152 extends between the contacts 126, 128 and electrically insulates the contact 126, 128 from one another.
The housing 114 is composed of a dielectric material, such as one or more plastics. The housing 114 may be manufactured via a molding process. The front panel 134 may be formed integral to the base panel 136 during a common molding process such that the housing 114 is a single, unitary component. In an alternative embodiment, the housing 114 may be an assembly of multiple discrete components coupled together. The front side 138 of the front panel 134 is shown in
In an embodiment, the housing 114 also defines at least one aperture 176 that is associated with each contact opening 174. In the illustrated embodiment, the housing 114 defines two apertures 176 proximate to each contact opening 174. One of the two apertures 176 is located vertically above the corresponding contact opening 174 (along the vertical axis 191 shown in
The nose cone 130 may be composed of a dielectric material, such as one or more plastics. The nose cone 130 optionally may be formed via a molding process. The nose cone 130 defines a cavity 178 that extends into the nose cone 130 from a front end 180 thereof. The cavity 178 aligns with one of the contact openings 174 when the nose cone 130 is coupled to the housing 114. The portion of the mating segment 156 of the outer contact 126 that protrudes from the front side 138 of the front panel 134 is received within the cavity 178. Thus, the nose cone 130 surrounds the portion of the contact subassembly 154 that protrudes frontward from the front panel 134 generally along the mating axis 193 (shown in
The nose cone 130 couples to the front panel 134 of the housing 114. For example, the nose cone 130 may include at least one lug 182 that extends rearward from a back wall 184 of the nose cone 130. Each lug 182 is configured to be received in a corresponding aperture 176 in the front panel 134. The nose cone 130 in the illustrated embodiment includes two lugs 182, but only one lug 182 is visible. The lugs 182 may be formed integral to the nose cone 130 as a discrete unitary component. The lugs 182 may be inserted into the corresponding apertures 176, such as via cold-staking, in order to secure the nose cone 130 to the front panel 134. Optionally, the lugs 182 may include a flange that compresses and/or deflects upon insertion and resiliently returns towards an uncompressed or undeflected state upon protruding beyond the rear side 140 to provide a mechanical lock. In other embodiments, the nose cone 130 may be coupled to the front panel 134 via an external fastener, such as a bolt or screw, an adhesive, or the like.
The EMI shield 124 in an embodiment is disposed between the nose cone 130 and the housing 114. The EMI shield 124 is composed of an electrically conductive material, such as one or more metals. The EMI shield 124 includes a plate 186 and spring fingers 188 extending from outer edges 190 of the plate 186. The spring fingers 188 are configured to engage the panel 106 (shown in
The nose cone 130 may provide structural support for the mating segment 156 of the outer contact 126, such as to prohibit the mating segment 156 from bending and twisting during mating and un-mating of the mating connector. For example, the nose cone 130 defines an annular shoulder 230 within the cavity 178. The annular shoulder 230 defines a reduced-diameter portion 232 of the cavity 178. The reduced-diameter portion 232 is more proximate to the back wall 184 of the nose cone 130 than to the front end 180 of the nose cone 130. An interior surface 234 of the annular shoulder 230 surrounds the mating segment 156 of the outer contact 126. The diameter of the reduced-diameter portion 232 may be equal to an outer diameter of the outer contact 126 within the cavity 178 such that the interior surface 234 constantly engages an exterior surface of the outer contact 126. Alternatively, the diameter of the reduced-diameter portion 232 may be at least slightly greater than the outer diameter of the outer contact 126 such that the interior surface 234 may not constantly engage the outer contact 126. The interior surface 234 of the annular shoulder 230 may provide a hard stop that surrounds the outer contact 126 to block the outer contact 126 from bending during mating and/or un-mating of the mating connector. Depending on the relative diameters of the outer contact 126 and the reduced-diameter portion 232 along the annular shoulder 230, the annular shoulder 230 may prohibit the mating segment 156 from any bending or from bending beyond a designated allowable threshold. The nose cone 130 is structurally secured to the housing 114 via the lugs 182, and the housing 114 is structurally secured to the circuit board 104 via the mounting posts 118. Thus, the annular shoulder 230 of the nose cone 130 may structurally tie the mating segment 156 of the outer contact 126 to the circuit board 104 through the housing 114.
In an embodiment, the mounting segment 158 of the outer contact 126 is disposed between the base panel 136 of the housing 114 and the circuit board 104. For example, the base panel 136 extends over (or above) the mounting segment 158 and the circuit board 104 extends under (or below) the mounting segment 158. The circuit board 104 may extend under all portions of the mounting segment 158 except for the portions of the grounding legs 204 of the mounting segment 158 that extend through the circuit board 104 for mounting the outer contact 126. The mounting segment 158 of the outer contact 126 may engage an inner surface 208 the base panel 136 that faces the circuit board 104. The base panel 136 of the housing 114 is independently mounted to the circuit board 104 via the mounting posts 118, so the engagement between the base panel 136 and the mounting segment 158 of the outer contact 126 may structurally reinforce the outer contact 126 to prohibit the outer contact 126 from bending, twisting, and/or breaking during mating or un-mating of the mating connector. The engagement between the base panel 136 of the housing 114 and the mounting segment 158 of the outer contact 126 may also mechanically reinforce the mounting of the outer contact 126 to the circuit board 104 by mechanically blocking the mounting segment 158 from lifting up from the top side 116 of the circuit board 104.
In an embodiment, the tunnels 210 define tunnel slots 218 that extend through tunnel walls 220. The tunnel slots 218 extend from a rear end 222 of the respective tunnel 210 in a direction towards the front panel 134. The tunnel slots 218 may extend less than half of the length of the respective tunnel 210. In the illustrated embodiment, each of the two tunnels 210 defines two tunnel slots 218, with one tunnel slot 218 located on each side of the apex 214 of the tunnel 210 along the lateral width of the housing 114. The tunnel slots 218 are each configured to receive a grounding leg 204 of the outer contact 126 within the tunnel 210. For example, a grounding leg 204 may extend out of the tunnel 210 through one of the tunnel slots 218. A distal section 240 of the grounding leg 204 outside of the tunnel 210 may be mechanically coupled and/or electrically terminated to the circuit board 104. For example, the distal section 240 may be through-hole mounted in a corresponding via 242 of the circuit board 104. The through-hole mounting may serve a dual function of mechanically coupling the grounding leg 204 in order to secure the outer contact 126 to the circuit board 104 and also electrically terminating the grounding leg 204 to provide a grounding path between the outer contact 126 and the circuit board 104.
In the illustrated embodiment, the base panel 136 defines at least one mounting slot 224 associated with each tunnel 210. The mounting slots 224 extend through the base panel 136 between the top side 142 and the bottom side 144. The base panel 136 may include one mounting slot 224 on both lateral sides of a corresponding tunnel 210. The mounting slots 224 may extend from the rear end 222 of the base panel 136 towards the front panel 134, similarly to the tunnel slots 218. In an embodiment, the rear grounding legs 204B of a respective outer contact 126 are configured to extend through both the tunnel slots 218 and the mounting slots 224. For example, each rear grounding leg 204B includes the distal section 240 and a proximal section 246 that is located between the distal section 240 and the spine portion 206 of the outer contact 126. The spine portion 206 is disposed within a corresponding tunnel 210. The proximal section 246 of one grounding leg 204B extends out of the tunnel 210 through one of the tunnel slots 218, and the distal section 240 of the same grounding leg 204B extends downward through one of the mounting slots 224 in the base panel 136 in order to mount to the circuit board 104 (e.g., by being received in one of the vias 242).
In an embodiment, the locations of the tunnel slots 218 and mounting slots 224 along the base panel 136 define stub portions 248 of the tunnel walls 220. The stub portions 248 are cantilevered and extend to the rear end 222 of the base panel 136. In an embodiment, when an outer contact 126 is loaded in corresponding tunnel 210, the rear grounding legs 204B at least partially surround the stub portions 248. For example, a stub portion 248 may be disposed laterally between the distal section 240 of one grounding leg 204B and the spine portion 206 of the outer contact 126. Thus, the stub portion 248 may be located within the open bottom of the mounting segment 158 of the outer contact 126. The stub portions 248 optionally may be the only portions of the base panel 136 (including the tunnels 210) that are radially interior and/or at least partially surrounded by the outer contacts 126 held within the tunnels 210.
The rear grounding legs 204B extending through the tunnel slots 218 and the mounting slots 224 interlocks the outer contact 126 and the base panel 136, which structurally ties the outer contact 126 to the base panel 136. Thus, at least some forces exerted on the outer contact 126 may be transferred to the base panel 136. The base panel 136 is mounted to the circuit board 104 independently from the outer contact 126 via the mounting posts 118 being received in the corresponding holes 120 of the circuit board 104. Thus, the base panel 136 of the housing 114 structurally supports the mounting segment 158 of the outer contact 126 by mechanically engaging the outer contact 126 to reinforce the mounting of the outer contact 126 to the circuit board 104. Since the outer contact 126 may be stamped and formed in an embodiment, the structural support provided by the housing 114 and the nose cone 130 of the header assembly 102 may prohibit the outer contact 126 from damage caused by bending and/or twisting during mating and un-mating of the mating connector relative to the header assembly 102.
It is to be understood that the above description is intended to be illustrative, and not restrictive. For example, the above-described embodiments (and/or aspects thereof) may be used in combination with each other. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from its scope. 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(f), 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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