The invention is related to an electrical cable connector, and particularly to the cable connector equipped with a shielding plate between two rows of cables. The instant application is related to a copending application having the same applicant, the same inventors, the same assignee and the same filing date with a title of “ELECTRICAL CABLE CONNECTOR WITH GROUNDING SHEET ”.
U.S. Pat. No. 9,257,801 discloses an electrical connector having a conductive shell, the terminal module assembled in the conductive shell and the shielding plate wherein the terminal module has a first terminal module and a second terminal module each having the corresponding conductive terminals therein, and the shielding plate is located between the first terminal module and the second terminal module and electrically and mechanically connected to the conductive shell. Anyhow, no direct connection occurs between the shielding plate and the grounding terminals of the conductive terminals.
It is desired to provide an improved connector with the shielding plate mechanically and electrically connected to the corresponding grounding terminals in a reliable and robust manner.
To achieve the above desire, an electrical cable connector includes a base, a plurality of terminals and an insulative block. The base includes a main body and a mating tongue extending forwardly from the main body. The mating tongue includes opposite mating faces. The terminal includes a front contacting section exposed upon the mating face, and a rear connecting section. All the terminals include the grounding terminals, the signal terminals and the power terminals. A first terminal module and a second terminal module are integrally assembled with the base, and each of the first terminal module and the second terminal module includes the insulator and the corresponding terminals embedded therein. The first terminal module and the second terminal module are stacked with each other with a metallic shielding plate therebetween. The shielding plate includes front spring fingers and rear spring fingers respectively mechanically and electrically connected with the contacting sections and connecting sections of the respective grounding terminals.
Reference will now be made in detail to the embodiments of the present disclosure. Referring to
The upper terminal module 2a and the lower terminal module 2b are similar to each other in a symmetrical arrangement in the vertical direction with the corresponding wires 1a and 1b respectively connected thereto.
The terminal 4 includes a plate 41 composed of in a front-to-back direction a front plate 411 and the rear plate 412 with an offset therebetween. The front plate 411 forms the contacting section 42 thereon for mating with a complementary connector while the rear plate 412 forms a longitudinal recess 431 to form the connecting section 43 for soldering to the corresponding wire 1. The contacting section 42 is exposed upon and flush with the mating surface 301. An alternate embodiment shown in
The upper terminal module 2a, as well as the lower terminal module 2b, includes an insulator 5 integrally formed with the corresponding terminals 4, the grounding bar 7 and the pressing block 8. The insulator 5 has the first section 51, the second section 52 and the third section 53. The front plate 411 of the terminal 4 including the contacting section 42 is embedded within the first section 51 wherein the contacting section 42 is exposed the exterior surface of the first section 51. The rear plate 412 with the connecting section 43 is embedded within the second section 52 wherein the connecting section 43 is exposed upon the exterior surface of the second section 52. The third section 53 forms a plurality of passageways 531 in alignment with the corresponding connecting sections 43, respectively, along the front-to-back direction, to receive the corresponding wires 1. An abutment section 54 is formed between the second section 52 and the third section 53 and forms a notch 541 in alignment with the corresponding passageway 531 so as to allow the inner conductor of the corresponding wire 1 to extend therethrough and soldered upon the corresponding connecting section 43.
The wires 1 includes a plurality of signal wires 11 and a plurality of power wires 12. The signal wire 11 is a co-axial wire while the power wire 12 has a single inner conductor. In this embodiment, the wires 11 arranged in one row, have two power wires 12 at two opposite ends and the signal wires 11 therebetween. The signal wire 11 includes an inner conductor 111, an inner insulator 112 surrounding the conductor 111, a metallic braiding layer 113 surrounding the inner insulator 112, and an outer insulator 114 surrounding the braiding layer 113 in a concentric manner. Front end sections of the conductor 111, the inner insulator 112, the braiding layer 113 and the outer insulator 114 are respectively exposed to an exterior in sequence. The power wire 12 includes a conductor 121 and an insulator 122 surrounding the conductor 121. The power wires 12 are connected to the power terminals of the terminal module, and the signal wires 11 are connected to the signal terminals of the terminal module. The grounding terminals 4G are commonly grounded by the grounding bar 7.
The grounding bar 7 includes a main body 71, a plurality of first arms 72 extending forwardly from the main body 71, and a plurality of second arms 73 extending rearwardly from the main body 71 and aligned with the corresponding first arms 72 in the front-to-back direction, respectively. The grounding bar 7 is located between the wires 71 and the shielding plate 6, and the braiding layers 113 of the wires 1 are soldered upon the main body 71. The first arms 72 extend forwardly and is terminated at a position similar to the conductor 111, and positioned upon the connecting sections 43, respectively. The second arms 73 are exposed outside of the contact module 2.
The wires 1 and the grounding bar 7 are firstly assembled to the corresponding insulator 5, and the pressing block 8 is assembled successively. The pressing block 8 is made of insulative material and assembled upon the third section 53 to cooperate with the third section 53 to sandwich the wires 1 therebetween. The pressing block 8 includes the receiving slots 81, 82 corresponding to the passageways 531 to receive the corresponding wires 1 and the first arms 72. Notably, the passageways 531 and the corresponding receiving slots 81 both of which receive the corresponding wires 1, are configured to be semi-circular while those for receiving the corresponding first contact 72 are configured to be rectangular.
The shielding plate 6 includes a plurality of front spring fingers 61 and a plurality of rear spring fingers 62 aligned with each other in a front-to-back direction while extending in opposite direction away from each other. The front spring finger 61 and the corresponding spring finger 62 extend oppositely in the vertical direction. The front spring finger 61a and the neighboring front spring fingers 61b extend oppositely in the vertical direction, and the rear spring fingers 62a and the neighboring rear spring fingers 62b extend in the same pattern. The shielding plate 6 has two rows of rectangular windows 63, and a linking section 64 is located between each paired windows 63. The front spring fingers 61 and the rear spring fingers 62 respectively extend from opposite edges of the corresponding linking section 64 toward the corresponding windows 63. The front spring finger 61 connects to the contacting section 42 and the rear spring finger 62 connects to the connecting section, respectively. The first section 51 of the insulator 5 forms a plurality of openings 511 respectively vertically aligned with the contacting sections 42, and the second section 52 of the insulator 5 forms a plurality of openings 521 respectively vertically aligned with the connecting sections 43 so as to allow the front spring fingers 61 to extend through the openings 511 to contact the corresponding contacting sections 42 of the grounding terminals 4G, and the rear spring fingers 62 to extend through the opening 521 to contact the corresponding connecting sections 43 of the grounding terminals 4G. At the same time, the second arms 73 are connected to the shielding plate 6 to form a path, thus reducing the EMI (Electro-Magnetic Interference). The shielding plate 6 extends out of the mating tongue 31 and divides the mating tongue 31 into two opposite parts symmetrically. The terminals 4 are aligned with the wires 1 and the first arms 72 of the grounding bar 7 in the front-to-back direction.
The insulator 5 further includes mounting posts 55 and the mounting holes 56, and the shielding plate 6 forms through holes 65 in alignment with the corresponding mounting posts 55 so as to have the mounting post 55 of the upper terminal module 2a extend through the corresponding through hole 65 into the mounting hole 56 of the lower terminal module 2b, and vice versa, for combining all the upper terminal module 2a, the lower terminal module 2b and the shielding plate 6 therebetween as an intermediate sub-assembly wherein each terminal module 2a, 2b is equipped with the corresponding grounding bar 7 and pressing block 8. After then, an outer insulator is applied upon the sub-assembly to enclose the front end region and the rear region of the sub-assembly to form the base 3 for completeness of the whole connector.
The method of making the instant connector includes steps as follows: (1) providing the upper terminal module 2a and the lower terminal module 2b each including an insulator 5 with a one row of terminals 4 via an insert-molding process wherein each terminal 4 includes a front contacting section 42 and a rear connecting section 43 both exposed upon a surface of the insulator 5; (2) providing two rows of wires each including signal wires 11 and power wires 12; (3) providing two grounding bars 7 each located outside of the corresponding insulator 5 and vertically inside the corresponding wires 1 with the braiding layer 113 of the corresponding signal wires 11 soldered thereon; (4) assembling the wires 1 with the associated grounding bar 7 into the corresponding terminal module 2a, 2b wherein the inner conductor 111 of the signal wires re connected to the connecting sections 43 of the terminals 2 while the first arms 72 of the grounding bar 7 are connected to the connecting sections 43 of the grounding terminals 4G; (5) providing a metallic shielding plate 6 sandwiched between the upper terminal module 21 and the lower terminal module 2b to form a sub-assembly with the second arms 72 of the corresponding grounding bar 7 pressing the shielding plate 6; (6) applying an insulative material upon an exterior of such a sub-assembly via an over-molding process to further cover front ends of the wires 1 so as to form the base 3 with the mating tongue 32 for finalizing the contour of the connector 100 wherein the contacting sections 42 of the terminals 4 are exposed upon the mating faces 301 of the mating tongue 32 while the connecting sections 43 and the conductor 111 of the wires are embedded within the insulative base 3.
In this embodiment, the wires 1 are firstly connected to the corresponding connecting sections 43 and successively applied with an insulative material thereon to form the insulative base 3, Under this situation, for the wire 11, the front end portion of the conductor 111 is exposed in front of the inner insulator 112, retained in the notch 541, further soldered upon the connecting section 43 and successively protectively covered by the insulative base 3; the inner insulator 112 located behind the exposed conductor 111, is retained in the passageway 531 and the corresponding receiving slot 81; the braiding layer 113 is located behind the rear end face 321 of the base 3 and connected/soldered to the main body 71 of the grounding bar 7; the shielding plate 6 rearwardly extends beyond the rear end face 321 with the second arms 73 of the grounding bar 7 connected thereto. The front spring fingers 61 and the rear spring fingers 62 are respectively connected the corresponding terminals 4 in the upper and lower rows wherein the front spring finger 61 connects to the front plate 411 and the rear spring finger 62 connects to the rear plate 412, In this embodiment, the conductor 111 of the wire 1 or the first arm 72 of the grounding bar 7 is connected upon an outer surface of the corresponding connecting section 43 while the rear spring finger 62 of the shielding plate 6 is connected to an inner surface of the corresponding connecting section 43. Notably, on one hand the shielding plate 6, the grounding bar 7, the braiding layers 113 of the signal wires 11, and the grounding terminals 4G all are grounded together in a robust manner, thus not only lowering EMI (Electron-Magnetic Interference) but also reducing the dimension of the whole connector. It should be noted that in
While a preferred embodiment in accordance with the present disclosure has been shown and described, equivalent modifications and changes known to persons skilled in the art according to the spirit of the present disclosure are considered within the scope of the present disclosure as described in the appended claims.
Number | Date | Country | Kind |
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201610618157.X | Aug 2016 | CN | national |
201610618160.1 | Aug 2016 | CN | national |
201610618201.7 | Aug 2016 | CN | national |