1. Field of the Invention
The present invention generally relates to a connector, and more particularly to an electrical connector.
2. The Related Art
With the wide application and the development of electronic technologies, volumes of connectors are smaller and transmission speeds of the connectors are higher, so high-frequency characteristics are requested more rigorous. When an electrical connector is used in an electronic device, crosstalk phenomena are easily caused. Especially, when a distance between signals and a reference plane of the electrical connector is increased or when strengths of the signals are increased or when a distance between every two adjacent terminals of the electrical connector is very close, near-end and far-end crosstalk interferences are caused that affects an integrity of the signals and results in a delay of the signals. Thus accuracies of transmitting the signals of the electrical connector are lowered.
In view of the above-mentioned problems of the electrical connector, an innovative electrical connector need be developed for effectively reducing the near-end and far-end crosstalk interferences.
An object of the present invention is to provide an electrical connector. The electrical connector includes an insulating housing, a dielectric body, a plurality of terminals integrally molded to the dielectric body, a shielding plate and a plurality of metal elements. The insulating housing has a top wall, a bottom wall, two lateral walls and a rear wall. An insertion space is formed among the top wall, the bottom wall, the two lateral walls and the rear wall. The terminals include signal terminals and grounding terminals. The shielding plate is integrally molded to the dielectric body. The dielectric body together with the terminals and the shielding plate is assembled to a rear end of the insulating housing. The metal elements are mounted to a top surface and a bottom surface of the dielectric body. Each of the metal elements has a base plate, and a touch portion extended from the base plate. The base plates of the metal elements are mounted to the top surface and the bottom surface of the dielectric body, respectively. A tail end of the touch portion contacts the shielding plate. One side of the touch portion contacts one of the grounding terminals.
As described above, the tail ends of the touch portions of the metal elements contact the shielding plate, and the one side of the touch portion of each of the metal elements contacts the one of the grounding terminals, so that a distance between signals and a reference plane of the electrical connector is decreased, a mutual inductance between specific circuits is effectively decreased, and an integrity of the signals is ensured. Thus, accuracies of transmitting the signals of the electrical connector are higher. As a result, near-end and far-end crosstalk interferences are effectively improved.
The present invention will be apparent to those skilled in the art by reading the following description, with reference to the attached drawings, in which:
With reference to
Referring to
The two rows of the terminal grooves 111 include an upper row of the terminal grooves 111 and a lower row of the terminal grooves 111 extending longitudinally. Fronts of the upper row of the terminal grooves 111 penetrate through the top wall 11 of the insulating housing 10 along the up-down direction, rears of the upper row of the terminal grooves 111 longitudinally penetrate through an upper portion of the rear wall 14 of the insulating housing 10. Fronts of the lower row of the terminal grooves 111 penetrate through the bottom wall 12 of the insulating housing 10 along the up-down direction, rears of the lower row of the terminal grooves 111 longitudinally penetrate through a lower portion of the rear wall 14 of the insulating housing 10. The upper row of the terminal grooves 111 are arranged transversely. The lower row of the terminal grooves 111 are arranged transversely.
A top surface of the top wall 11 and a bottom surface of the bottom wall 12 of the insulating housing 10 are recessed inward to form two fastening cavities 112 communicated with the terminal grooves 111. One of the fastening cavities 112 in the top wall 11 is communicated with the upper row of the terminal grooves 111. The other fastening cavity 112 in the bottom wall 12 is communicated with the lower row of the terminal grooves 111. Two opposite sides of an inner wall of each of the fastening cavities 112 open two insertion holes 113 communicated with the insertion space 15. A front end of the inner wall of each of the fastening cavities 112 opens a plurality of avoiding grooves 114 communicated with the insertion space 15. A middle of a rear surface of the rear wall 14 of the insulating housing 10 is recessed frontward to form a fastening slot 141 extending transversely.
The two extending walls 17 are spaced from each other to form an assembling opening 16 between the two extending walls 17. The insulating housing 10 opens two clamping grooves 131 transversely penetrating through middles of the two lateral walls 13 and the two extending walls 17, and longitudinally penetrating through rear surfaces of the two extending walls 17 of the insulating housing 10, respectively. Front ends of the two clamping grooves 131 are communicated with the insertion space 15. Rear ends of the two clamping grooves 131 are communicated with the assembling opening 16. An upper side and a lower side of each side wall of the assembling opening 16 extend inward to form a pair of guide rails 132 for guiding the dielectric body 20. An inner side of each of the guide rails 132 is recessed outward to form a restricting groove 133.
Referring to
Referring to
The upper row of the terminals 30 are molded to the upper portion of the base body 21 and arranged transversely. The lower row of the terminals 30 are molded to the lower portion of the base body 21 and arranged transversely. The upper row of the terminals 30 are molded to the upper row of the fixing grooves 26. The lower row of the terminals 30 are molded to the lower row of the fixing grooves 26. The lower row of the terminals 30 is located under the upper row of the terminals 30. Preferably, the upper row of the terminals 30 is symmetrical to the lower row of the terminals 30. The fastening portion 31 of each of the terminals 30 is molded in the base body 21. The contact portions 32 of the terminals 30 project beyond the front surface of the base body 21. The soldering portions 33 of the terminals 30 project beyond the rear surface of the base body 21.
Referring to
Referring to
Referring to
Two opposite sides of a front edge of the fastening piece 71 extend frontward to form two elastic arms 73 arched outward. Each of the elastic arms 73 is shown an arch-shape. Distal ends of the two elastic arms 73 are connected with a connecting arm 74. Several portions of a front edge of the connecting arm 74 are curved inward and rearward, and then arched inward to form a plurality of resilient portions 75. Several portions of a rear edge of the connecting arm 74 forms a plurality of ground portions 76 extending rearward and inclining outward. The ground portions 76 are respectively corresponding to the resilient portions 75. Two opposite sides of a middle of the front edge of the fastening piece 71 extend frontward to form two extending arms 77. Two portions of a middle of the rear edge of the fastening piece 71 slantwise extend rearward and outward to form two abutting portions 78.
Referring to
The insulation films 60 are respectively mounted to the two fastening cavities 112 and cover the front ends of the terminals 30. The two shielding elements 70 are fastened to the two fastening cavities 112 and partially cover the two insulation films 60, respectively. The fastening piece 71, the elastic arms 73, the connecting arm 74, the two extending arms 77 and the two abutting portions 78 of each of the two shielding elements 70 are received in one of the two fastening cavities 112. The fastening pieces 71, the two extending arms 77 and the two abutting portions 78 of the two shielding elements 70 block the two insulation films 60 from falling off by virtue of the two shielding elements 70 partially covering the respective insulation films 60. The two insertion arms 72 of each of the shielding elements 70 are inserted into the two insertion holes 113, respectively for fastening each of the shielding elements 70 firmly. The resilient portions 75 are received in the avoiding grooves 114 and project into the insertion space 15.
The ground portions 76 and the abutting portions 78 of the two shielding elements 70 project beyond the top surface of the top wall 11 and the bottom surface of the bottom wall 12, respectively. Each of the insulation films 60 is clamped between the terminals 30 and one of the shielding elements 70. When the terminals 30 expand outward to generate elastic deformations, the insulation films 60 are capable of effectively preventing the terminals 30 contacting with the shielding elements 70 for ensuring a better electrical performance of the electrical connector 100.
At last, the metal elements 50 are mounted to a top surface and a bottom surface of the dielectric body 20. The base plates 51 of the metal elements 50 are mounted to the top surface and the bottom surface of the dielectric body 20, respectively. A tail end of the touch portion 52 contacts the shielding plate 40. One side of the touch portion 52 of each of the metal elements 50 contacts one of the grounding terminals 302. Specifically, the base plates 51 of the metal elements 50 are received in the recesses 23. The touch portion 52 of each of the metal elements 50 passes through the insertion slot 24. The tail ends of the touch portions 52 contact the main plate 41 of the shielding plate 40. The fastening portion 31 of each of the grounding terminals 302 is partially exposed to the insertion slot 24. The touch portions 52 of the metal elements 50 contact the fastening portions 31 of the grounding terminals 302.
As described above, the tail ends of the touch portions 52 of the metal elements 50 contact the shielding plate 40, and the one side of the touch portion 52 of each of the metal elements 50 contacts the one of the grounding terminals 302, so that a distance between signals and a reference plane of the electrical connector 100 is decreased, a mutual inductance between specific circuits is effectively decreased, and an integrity of the signals is ensured. Thus, accuracies of transmitting the signals of the electrical connector 100 are higher. As a result, near-end and far-end crosstalk interferences are effectively improved.
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