The present invention relates to a cable connector assembly having a cable of a flat structure.
U.S. Patent Application Publication No. 2016/0079689, published on Mar. 17, 2016, shows a cable connector assembly including a connector and a cable electrically connected to the connector. The cable includes a plurality of core wires and associated outer insulative layers. The cross-section of the cable is circular such that the cable has a large dimension in the thickness direction.
An improved cable connector assembly is desired.
An object of the present invention is to provide an improved cable connector assembly with a cable having a small dimension in the thickness direction.
To achieve the above-mentioned object, a cable connector assembly for being mated with a mating connector along a mating direction includes a mating member; a cable electrically connected with the mating member, and a shielding shell having an end mounted on the mating member, and an opposite end mounted on the cable, the shielding shell comprising a first shell and a second shell mated with the first shell along a transverse direction perpendicular to the mating direction, wherein each of the first shell and the second shell has an asymmetrical structure.
Referring to
Referring to
All the core wires 21 except the pair of power signal wires 217 are coaxial wires. The coaxial lines include a center conductor 218, an insulating layer 219 covering the center conductor 218 and a second braided layer 220 wrapped around the insulating layer 219. The first and second braided layers 23, 220 can effectively weaken the external radiation of the center conductor 218 and strengthen its own anti-interference ability.
The core wires 21 are arranged up and down in two rows. An upper row includes two pairs of high-speed signal lines 212, the pair of low-speed signal lines 216, a spare signal line 213 and a power signal line 217. The lower row includes two pairs of high-speed signal lines 212, a detection signal line 214, a power supply line 215, a spare signal line 213 and a power signal line 217. The cable 2 is flat and is divided into a first side 201 and a second side 202 in a width direction. The two pairs of high-speed signal lines 212 are located on the first side 201 and are oppositely disposed one above the other. The power signal lines 217 are located on the second side 202 and are oppositely disposed one above the other. The other two pairs of high-speed signal lines 212 are located inside the power signal lines 217 in the width direction. The pair of low-speed signal lines 216 and a spare signal line 213 are disposed between the two pairs of high-speed signal lines 212 in the upper row, and the spare signal lines 213 are located between the low-speed signal lines 216 and the high-speed signal lines 212 located on the first side 201. The detection signal line 214 in the lower row is adjacent to the high speed signal lines 212 on the first side 201. The lower spare signal line 213 in the low row is adjacent to the high speed signal lines 212 near the second side 202. The power supply line 215 for powering the connector 1 internally is located between the detection signal line 214 and the spare signal line 213 in the lower row. This arrangement allows the spare signal lines 213 to be arranged separately, effectively preventing them from coupling with each other.
The cable 2 is not provided with a ground wire, instead, the second braided layer 220 of each coaxial line serves as a ground wire, and can satisfy a voltage drop of 250 mV when there is a current of 3 A or 5 A. The specifications of the two power signal lines 217 can be flexibly designed with 26 or 24 AWG (American wire gauge), and can meet 500 mV voltage drop when there is 3 A or 5 A current.
The PCB 12 includes an upper surface and a lower surface, and the front and back conductive sheets are symmetrical, because it can be inserted along both of the forward and backward direction. The PCB 12 defines a plurality of first conductive pads 120 on a front end thereof, a grounding region 121 on a rear end and a plurality of second conductive pads 122 between the first conductive pads 120 and the grounding region 121. Both of the upper surface and the lower surface define the first conductive pads 120, the grounding region 121 and the second conductive pads 122. The first conductive pads 120 are electrically connected to the contacts of the mating member 11. The grounding regions 121 are soldered to the second braided layers 220. Each of the center conductors 218 is electrically connected to the second conductive pads 122 corresponding on the front and rear ends of the PCB 12 respectively.
The shielding case/shell 14 includes a first case/shell 140 and a second case/shell 141. The first case 140 includes a first side 1400, an upper surface 1401, and a tail portion 1402 extending from the upper surface 1401 toward the extending direction of the cable 2. The second case 141 includes a second side 1410, a lower surface 1411 and a tubular retaining portion 1412 extending, via an extension section 1413, from the lower surface 1411 towards the extending direction of the cable 2. The end of the first braided layer 23 of the cable 2 is overturned on the surface of the cable 2, and is wrapped with a copper foil 25. The tail portion 1402 extends to the copper foil 25. The retaining portion 1412 is held on the tail portion 1402 and the copper foil 25 to be caulked on the cable 2. The first case 140 and the second case 141 are assembled together by laser welding. The shielding case 14 and the mating member 11 are also assembled by laser welding. In this embodiment, a tubular insulative or rubbery front cap 30 surrounds the mating member 11 and is enclosed in the shielding case 14 for better sealing performance, and a pair of insulative or rubbery rear caps 32 sandwiched between the copper foil 25 and the outer case 15 for compensating the contour difference between the outer profile of the cable 2 with the associated copper foil 25 thereon and that of the outer case 15 which is essentially of a capsular cross-sectional configuration.
Notably, the first case 140 and the second case 141 are welded along the pair of seam structures 146, i.e., the ridges or edges, in the front-to-back direction wherein the pair of seam structures are located opposite to each other in a diagonal direction rather than in the vertical direction or the horizontal direction. Understandably, this diagonal or oblique arrangement of the seam structures is to avoid interference, at the same level, with the corresponding extension section 1413 and the corresponding tail portion 1402 both of which extend preferably along a centerline of the whole cable connector assembly for force balancing consideration. In other words, the seam structure 146 is intentionally spaced from the centerline with a distance in the transverse direction perpendicular to the front-to-back direction. Furthermore, the seam structure forms a zigzag configuration for enhancing the securement thereof. Notably, even though each of the first case 140 and the second case 141 is essentially asymmetrically arranged in itself with regard to the centerline measured either in the vertical direction or the horizontal direction, the first case 140 and the second case 141 are essentially mutually symmetrically arranged with each other via the diagonal direction, disregarding the rear retaining portion 1412 and the tail portion 1402.
Number | Date | Country | Kind |
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201710568686.8 | Jul 2017 | CN | national |
Number | Date | Country | |
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Parent | 16034771 | Jul 2018 | US |
Child | 16408480 | US |