The subject matter herein relates generally to coaxial cable assemblies.
Coaxial cable assemblies typically include a connector terminated to an end of a coaxial cable. The connector includes a center contact terminated to an end of a center wire of the coaxial cable and a shielded body terminated to a cable braid or outer conductor of the coaxial cable. The connector is terminated to a complementary mating connector (e.g. plug and receptacle) having a mating contact held by the mating connector. The mating connector may be terminated directly to a circuit board to create an interface for the connector to electrically connect to the circuit board.
Such coaxial cable assemblies are not without disadvantages. For example, the system includes many components and interfaces between the signal pad of the circuit board and the center wire of the coaxial cable assembly. For example, a typical system will include three interfaces defined by 1) the circuit board and the mating contact, 2) the mating contact and the center contact, and 3) the center contact and the center wire. Each interface may cause signal degradation. Additionally, the mating connector and the connector of the coaxial cable assembly have a stack-up issue, increasing the overall height or profile above the circuit board. Some applications desire low-profile connectors. Furthermore, mounting the mating connector to the circuit board increases assembly time, such as for soldering the mating contact to the circuit board.
A need remains for a coaxial cable assembly that can be connected to a circuit board in a cost effective and reliable manner.
In one embodiment, a coaxial cable assembly is provided having a coaxial cable having a terminating end and a conductor being exposed at the terminating end. A cable housing holds the coaxial cable and has a conductor slot receiving the exposed conductor. A cable shield is coupled to the cable housing and provides electrical shielding for the terminating end of the coaxial cable. The cable housing is configured to be coupled to a circuit board such that the exposed conductor directly engages a signal pad of the circuit board for electrical connection thereto.
Optionally, the conductor may be configured to be directly coupled to the signal pad of the circuit board at a separable interface. The conductor may include a center wire of the coaxial cable held within the conductor slot for directly engaging the signal pad. The conductor may include a center wire of the coaxial cable and a wedge contact terminated to the center wire with the wedge contact being held within the conductor slot for directly engaging the signal pad.
Optionally, the cable housing may include a nose at an end of the cable housing with the conductor slot provided at the nose and the conductor exposed at the nose for direct mounting to the signal pad. The cable housing may be spring biased against the circuit board with the exposed conductor being compressed against the signal pad when the cable housing is coupled to the circuit board. The cable shield may be electrically connected to an outer conductor of the coaxial cable. The cable housing may include a crown within the cable shield where a center wire of the coaxial cable is bent about the crown to define an apex configured to be compressed against the signal pad.
Optionally, the assembly may include a base shell configured to be mounted to the circuit board. The base shell may include a spring lever that is spring biased against at least one of the cable housing and the cable shield to press the exposed conductor against the signal pad. The cable housing may include a bottom configured to face the circuit board.
In another embodiment, a coaxial cable assembly is provided having a base shell configured to be coupled to a circuit board over a signal pad of the circuit board. The assembly also includes a coaxial cable having a terminating end with a conductor being exposed at the terminating end. A cable housing holds the coaxial cable and has a conductor slot receiving the exposed conductor. A cable shield is coupled to the cable housing and provides electrical shielding for the terminating end of the coaxial cable. The cable housing and cable shield are loaded into a cavity of the base shell and the base shell holds the cable housing such that the exposed conductor is configured to directly engage the signal pad of the circuit board for electrical connection thereto.
In a further embodiment, a coaxial cable assembly is provided having a coaxial cable having a terminating end. A conductor is exposed at the terminating end. The conductor includes a center wire of the coaxial cable and the conductor includes a wedge contact terminated to an end of the center wire. The assembly includes a cable housing holding the coaxial cable and having a conductor slot receiving the wedge contact. A cable shield is coupled to the cable housing and provides electrical shielding for the terminating end of the coaxial cable. The cable housing is configured to be coupled to a circuit board such that the wedge contact directly engages a signal pad of the circuit board for electrical connection thereto.
The coaxial cable assembly 100 includes a coaxial cable 104, a cable housing 106, a cable shield 108 and a base shell 110. The coaxial cable 104, cable housing 106 and cable shield 108 define a cable subassembly 111 configured to be inserted into the base shell 110 to electrically terminate the coaxial cable 104 to the circuit board 102. The base shell 110 is mounted directly to the circuit board 102. The coaxial cable 104 is received in the cable housing 106 and the cable shield 108 is coupled to the cable housing 106 to provide electrical shielding for the coaxial cable 104. The coaxial cable 104, cable housing 106 and cable shield 108 are loaded into the base shell 110 to directly couple the coaxial cable 104 to the circuit board 102.
As shown in
The exposed portion of the conductor 112 is configured to be directly electrically connected to the circuit board 102. The exposed portion of the outer conductor 116 is configured to be electrically connected to the cable shield 108 and/or the base shell 110. In an exemplary embodiment, the base shell 110 presses against the cable shield 108 and/or cable housing 106 to press the center wire 112 against the circuit board 102 to make an electrical connection therewith. A separable, compressible electrical connection is made between the center wire 112 and the circuit board 102, such as to a signal pad on the circuit board 102.
The cable housing 106 includes a cable channel 122 that receives coaxial cable 104. Optionally, the coaxial cable 104 may be held in the cable channel 122 by an interference fit. Alternatively, retention features may be provided to secure the coaxial cable 104 within the cable channel 122. The cable channel 122 may be shaped to receive the coaxial cable 104. Optionally, the cable channel 122 may receive different diameter coaxial cables 104 to accommodate different size coaxial cables 104.
The cable housing 106 includes a nose 124 at a front end of the cable housing 106. A conductor slot 126 is provided at the nose 124. Optionally, the conductor slot 126 may be open at a front of the nose 124. Alternatively, the conductor slot 126 may be an internal passage through the nose 124. The conductor slot 126 receives the center wire 112 and may receive a portion of the insulator 114. Optionally, the conductor slot 126 may receive a portion of the outer conductor 116. During assembly, the terminating end 120 of the coaxial cable 104 is wrapped around the nose 124 such that the center wire 112 is received in the conductor slot 126. The center wire 112 wraps around a bottom 128 of the cable housing 106. The bottom 128 is generally opposite the cable channel 122. The cable housing 106 is received in the base shell 110 such that the bottom 128 extends along the circuit board 102. The exposed portion of the center wire 112 is exposed along the bottom 128 for terminating directly to the circuit board 102.
The cable housing 106 includes opposite sides 130, 132. The sides 130, 132 have catches 134 that extend outward therefrom. The catches 134 are used to secure the cable shield 108 to the cable housing 106. The sides 130, 132 extend to a top 136 of the cable housing 106. In an exemplary embodiment, the cable channel 122 is open through the top 136 such that the coaxial cable 104 may be loaded onto the cable channel 122 through the open top 136. Alternatively, the top 136 may be closed and the coaxial cable 104 may be loaded through a rear 138 of the cable housing 106.
The cable shield 108 is configured to be coupled to the cable housing 106. In an exemplary embodiment, the cable shield 108 is manufactured from a metal material, such as a copper material or another conductive material, to provide electrical shielding for the cable subassembly 111. In an exemplary embodiment, the cable shield 108 may be a stamped and formed part. The cable shield 108 includes sides 140, 142 and a top 144 extending between the sides 140, 142. Windows 146 are open through the sides 140, 142. The windows 146 receive the catches 134 when the cable shield 108 is coupled to the cable housing 106.
The cable shield 108 includes a strain relief 148 at a rear 150 of the cable shield 108. The strain relief 148 is configured to be coupled to the coaxial cable 104 to provide strain relief between the cable subassembly 111 and the coaxial cable 104. Optionally, the strain relief 148 may be crimped to the coaxial cable 104. Other securing means may be used in alternative embodiments to secure the cable shield 108 to the coaxial cable 104.
The cable shield 108 includes a spring finger 152 at a front 154 of the cable shield 108. The spring finger 152 extends along the nose 124. The spring finger 152 is configured to engage the exposed portion of the outer conductor 116 when the cable shied 108 is coupled to the cable housing 106. The spring finger 152 may be biased against the outer conductor 116 to ensure an electrical connection is maintain between the cable shield 108 and the outer conductor 116. The spring finger 152 may directly engage the nose 124. In an exemplary embodiment, the spring finger 152 is configured to engage the insulator 114 forward of the outer conductor 116. The spring finger 152 presses against the insulator 114 to hold the insulator 114 and conductor 112 (shown in
The exposed portion of the conductor 112 includes a mating interface 160 at the apex of the exposed portion of the conductor 112. The mating interface 160 is configured to be compressed against the circuit board 102. The mating interface 160 is separable from the circuit board 102. The mating interface 160 makes an electrical connection directly to the circuit board 102 without a soldered connection therebetween. The mating interface 160 makes an electrical connection with the circuit board 102 without another component or interface there between, such as a contact or terminal therebetween. A single interface is defined between the center wire 112 and the signal pad of the circuit board 102.
As shown in
The base shell 110 includes a spring lever 178 proximate to a front 180 of the base shell 110. A cavity 182 is defined between the side walls 174, 176 and the spring lever 178. The cavity 182 receives the cable subassembly 111. In an exemplary embodiment, the base shell 110 includes retention tabs 184 extending into the cavity 182 from the side walls 174, 176. The retention tabs 184 are located proximate to a rear of the base shell 110. The retention tabs 184 are configured to engage the cable subassembly 111 to hold the cable subassembly 111 within the cavity 182. For example, the retention tabs 184 are configured to engage the rear 138 of the cable housing 106 to restrict pull out of the cable subassembly 111 from the cavity 182. The retention tabs 184 resist reward movement of the cable subassembly 111 once the cable subassembly 111 is loaded into the cavity 182.
The base shell 110 includes latches 188 extending from the side walls 174, 176. The latches 188 are used to secure a cover 190 of the base shell 110 over the cable subassembly 111. The cover 190 extends from the front 180 of the base shell 110. In the illustrated embodiment, the cover 190 is pivotally coupled to the base 170. After the cable subassembly 111 is loaded into the cavity 182, the cover 190 is closed to hold the cable subassembly 111 in the cavity 182. The cover 190 includes latching tabs 192 that interact with the latches 188 to secure the cover 190 to the side walls 174, 176. Optionally, the cover 190 may press against the cable subassembly 111 to press the cable subassembly 111 against the circuit board 102.
In an exemplary embodiment, the cover 190 includes a grounding finger 194 that is configured to be spring biased against the cable shield 108. The grounding finger 194 electrically couples the base shell 110 to the cable shield 108. The grounding finger 194 may impart a spring force against the top of the cable subassembly 111 to press the cable subassembly downward against the circuit board 102.
During assembly, the cable subassembly 111 is plugged into the base shell 110. Optionally, the cable subassembly 111 may be loaded into the cavity 182 at an angle and then rotated into final position. The nose 124 is loaded into the cavity 182 under the spring lever 178. The spring lever 178 engages a top of the nose 124 to press the cable subassembly 111 downward into the circuit board 102. In an exemplary embodiment, the spring lever 178 engages the spring finger 152 on the cable shield 108 to electrically connect the base shell 110 to the cable shield 108. In an exemplary embodiment, the spring lever 178 imparts a vertically downward force onto the cable subassembly 111 directly above the exposed portion of the wire 112 (shown in
The coaxial cable assembly 100 is electrically connected to the circuit board 102. The exposed portion of the conductor 112 directly engages the circuit board 102. The coaxial cable 104 is wrapped around the nose 124. The end 162 of the conductor 112 is received in the well 164 and secured therein. The mating interface 160 is defined at the apex or lowest point of the conductor 112.
In an exemplary embodiment, the cable housing 106 includes a crown 196. The conductor 112 is bent around the crown 196 and is positioned for direct electrical connection with the circuit board 102. In an exemplary embodiment, the cable housing 106 includes a foot 198 proximate to the rear 138. The foot 198 positions the bottom 128 of the cable housing 106 along the circuit board 102. In an exemplary embodiment, the foot 198 is co-planar with the mating interface 160 for mounting to the circuit board 102.
Returning to
The cable housing 206 includes a cable channel 222 that receives the coaxial cable 204. The cable housing 206 includes a nose 224 at a front end of the cable housing 206. A conductor slot 226 is provided at the nose 224. Optionally, the conductor slot 226 may be open internally, and the front of the nose 224 may be closed in front of the conductor slot 226. The conductor slot 226 is an internal passage through the nose 224. The conductor slot 226 receives the center wire 212 and may receive a portion of the insulator 214. Optionally, the conductor slot 226 may receive a portion of the outer conductor 216. As shown in
The cable housing 206 includes opposite sides 230, 232. The sides 230, 232 have catches 234 that extend outward therefrom. The catches 234 are used to secure the cable shield 208 to the cable housing 206. The sides 230, 232 extend to a top 236 of the cable housing 206. In an exemplary embodiment, the cable channel 222 is open through the top 236 such that the coaxial cable 204 may be loaded onto the cable channel 222 through the open top 236. Alternatively, the top 236 may be closed and the coaxial cable 204 may be loaded through a rear 238 of the cable housing 206.
The cable shield 208 is configured to be coupled to the cable housing 206. In an exemplary embodiment, the cable shield 208 is manufactured from a metal material, such as a copper material or another conductive material, to provide electrical shielding for the coaxial cable assembly 200. In an exemplary embodiment, the cable shield 208 may be a stamped and formed part. The cable shield 208 includes sides 240, 242 and a top 244 extending between the sides 240, 242. The sides 240, 242 extend along the sides 230, 232 to clip the cable shield 208 onto the cable housing 206. The catches 234 are positioned behind the sides 240, 242 to hold the cable shield 208 from sliding backwards off of the cable housing 206.
The cable shield 208 includes a strain relief 248 at a rear 250 of the cable shield 208. The cable shield 208 includes a spring finger 252 configured to engage the exposed portion of the outer conductor 216 when the cable shied 208 is coupled to the cable housing 206.
With reference to
After the cable subassembly 211 is loaded into the cavity 282, the cover 290 is closed to hold the cable subassembly 211 in the cavity 282. The cover 290 includes a grounding finger 294 that is configured to be spring biased against the cable shield 208. The grounding finger 294 electrically couples the base shell 210 to the cable shield 208. The grounding finger 294 may impart a spring force against the top of the cable subassembly 211 to press the cable subassembly downward against the circuit board 202.
The exposed portion of the conductor 212 includes a mating interface 260 at the apex of the exposed portion of the conductor 212. The mating interface 260 is configured to be compressed against the circuit board 202. The mating interface 260 is separable from the circuit board 202. The mating interface 260 makes an electrical connection directly to the circuit board 202 without a soldered connection therebetween. The mating interface 260 makes an electrical connection with the circuit board 202 without another component or interface therebetween, such as a contact or terminal therebetween. A single interface is defined between the center wire 212 and the signal pad of the circuit board 202.
Returning to
The cable housing 306 includes a cable channel 322 that receives the coaxial cable 304. The cable housing 306 includes a nose 324 at a front end of the cable housing 306. A conductor slot 326 is provided at the nose 324. Optionally, the conductor slot 326 may be open at the front of the nose 324 for receiving the wedge contact 313 through the front. The conductor slot 326 may be open between the front and the cable channel 322 to allow the center wire 312 to pass through the conductor slot 326 form the cable channel 322 for terminating the wedge contact 313 to the center wire 312. The conductor slot 326 receives the center wire 312 and may receive a portion of the insulator 314. Optionally, the conductor slot 326 may receive a portion of the outer conductor 316.
The cable housing 306 includes opposite sides 330, 332. The sides 330, 332 have catches 334 that extend outward therefrom. The catches 334 are used to secure the cable shield 308 to the cable housing 306. The sides 330, 332 extend to a top 336 of the cable housing 306. In an exemplary embodiment, the cable channel 322 is open through the top 336 such that the coaxial cable 304 may be loaded onto the cable channel 322 through the open top 336. Alternatively, the top 336 may be closed and the coaxial cable 304 may be loaded through a rear 338 of the cable housing 306.
The cable shield 308 is configured to be coupled to the cable housing 306. In an exemplary embodiment, the cable shield 308 is manufactured from a metal material, such as a copper material or another conductive material, to provide electrical shielding for the coaxial cable assembly 300. In an exemplary embodiment, the cable shield 308 may be a stamped and formed part. The cable shield 308 includes sides 340, 342 and a top 344 extending between the sides 340, 342. The sides 340, 342 extend along the sides 330, 332 to clip the cable shield 308 onto the cable housing 306. The catches 334 are positioned behind the sides 340, 342 to hold the cable shield 308 from sliding backwards off of the cable housing 306.
The cable shield 308 includes a strain relief 348 at a rear 350 of the cable shield 308. The cable shield 308 includes a spring finger 352 configured to engage the exposed portion of the outer conductor 316 when the cable shied 308 is coupled to the cable housing 306.
With reference to
After the cable subassembly 311 is loaded into the cavity 382, the cover 390 is closed to hold the cable subassembly 311 in the cavity 382. The cover 390 includes a grounding finger 394 that is configured to be spring biased against the cable shield 308. The grounding finger 394 electrically couples the base shell 310 to the cable shield 308. The grounding finger 394 may impart a spring force against the top of the cable subassembly 311 to press the cable subassembly downward against the circuit board 302.
The wedge contact 313 defines the exposed portion of the conductor 301 that is configured to be compressed against the circuit board 302. The mating interface 360 is separable from the circuit board 302. The mating interface 360 makes an electrical connection directly to the circuit board 302 without a soldered connection therebetween. The mating interface 360 makes an electrical connection with the circuit board 302 without another component or interface therebetween, such as a mating contact or mating terminal therebetween. Only two interfaces are defined between the center wire 312 and the signal pad of the circuit board 302, namely the interface between the center wire 312 and the wedge contact 313 and the interface between the wedge contact 313 and the signal pad of the circuit board 302.
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, sixth paragraph, unless and until such claim limitations expressly use the phrase “means for” followed by a statement of function void of further structure.