1. Field of the Invention
The present invention generally relates to a connector, and more particularly to an electrical connector adapted for electrically connecting with a mating plug.
2. The Related Art
A portable electronic device is usually equipped with an electrical connector for electrically connecting with a mating plug, such as a universal serial bus (USB) plug. The conventional electrical connector generally involves an insulating housing, a plurality of terminals mounted in the insulating housing, and a shell coupled with the insulating housing to form an insertion chamber for receiving the USB plug. The shell, as well as we know, is often punched a plurality of buckling tabs. The buckling tabs extend into the insertion chamber to rest against the USB plug resiliently for making the USB plug connect with the terminals steadily. However, with frequent insertion and extraction operation of the USB plug, the resilience of the buckling tabs decreases gradually, which may affect the steady connection between the electrical connector and the USB plug so as to reduce usage life of the electrical connector.
An object of the present invention is to provide an electrical connector with a structure capable of fixing an inserted mating plug firmly for a long time. The electrical connector has an insulating housing defining a recess. A receiving plate is extended frontward from a rear surface of the recess and spaced apart from a bottom surface thereof. A plurality of terminals are received in the receiving plate. A shell is coupled with the insulating housing to form an insertion space where the receiving plate is located for allowing the mating plug to insert therein and receive the receiving plate. The shell has a connecting plate located between the receiving plate and the bottom surface of the recess. A portion of the connecting plate is extended and curved upwards and then curved downwards and upwards sequentially to form a substantial split ring-shaped resilient element. The resilient element comprises an upper resistive portion extended from the connecting plate and located adjacent to the receiving plate and a lower resistive portion opposite to the upper resistive portion and located adjacent to the bottom surface of the recess. A free end of the lower resistive portion extends obliquely upwardly to form a connecting portion. A distal end of the connecting portion forms a propping portion located above the connecting plate. When the mating plug is inserted, one of the upper resistive portion and the propping portion resists the mating plug firstly to make the other thereof uplift under the lower resistive portion resisting the bottom surface of the recess, and then the other thereof begins to resist the mating plug to do a reaction to the one thereof.
As described above, the electrical connector has the upper resistive portion and the propping portion, which are both against the inserted mating plug. Furthermore, the upper resistive portion makes the propping portion uplift when the upper resistive portion is pressed downwardly, and the propping portion is also enable to raise the upper resistive portion when the propping portion is pressed downwardly, accordingly, which not only enhances the insertion and withdrawal force between the electrical connector and the mating plug, but also prolongs usage life of the electrical connector.
The present invention will be apparent to those skilled in the art by reading the following description, with reference to the accompanying drawings, in which:
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The second shell 50 assembled to the insulating housing 10 from a front direction has a basic plate 51 of rectangular shape. The basic plate 51 has a bottom edge bent rearward to form a stopping piece 54 inserted into the stopping cavity 14 of the insulating housing 10 for fixing the second shell 50 to the insulating housing 10. Two opposite sides of the basic plate 51 are respectively curved rearwards to form a mating plate 55. The mating plate 55 has two fixing holes 551 corresponding to the corresponding fixing pieces 324 for securing the first shell 30 and the second shell 50. A top edge of the basic plate 51 is bent rearward to form a connecting plate 52 underlying the receiving plate 12 with a predetermined distance. The connecting plate 52 has two oblong holes 522, arranged side by side. Middles of both opposite sides of the connecting plate 52 respectively project outwards to form a patch 521 corresponding to the slot 323 for fixing the first shell 30 and the second shell 50. A rear edge of the connecting plate 52 is connected with two buckling components 53.
The buckling component 53 has a resilient element 530 extended upwards from the rear edge of the connecting plate 52, and then curved downwards and upwards sequentially. The resilient element 530 is substantially a split ring shape, and defines an upper resistive portion 531 of arc shape adjacent to the receiving plate 12 and a lower resistive portion 532 of arc shape disposed below the upper resistive portion 531 and spaced away from the bottom surface 111. The buckling component 53 further has a connecting portion 533 extending obliquely upwardly towards the corresponding hole 522 from a free end of the lower resistive portion 532. A distal end of the connecting portion 533 is curved downwards to form a propping portion 534 of arc shape. The propping portion 534 passes through the hole 522 and exceeds the connecting plate 52.
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When a USB plug 2 is partly inserted into the electrical connector 1 to press the propping portion 534 of the buckling component 53 downwardly, the upper resistive portion 531 is raised. When the USB plug 2 is continuously pushed into the insertion space 34, the upper resistive portion 531 is pressed downwardly to do a reaction to the propping portion 534, namely, making the propping portion 534 move upward. At this time, the lower resistive portion 532 resiliently leans on the bottom surface 111 for supporting the upper resistive portion 531 and the propping portion 534. In addition, the resistive tabs 312, 322 are all against the USB plug 2 for fixing the USB plug 2.
As described above, the buckling component 53 of the electrical connector 1 has the upper resistive portion 531 and the propping portion 534, which are both against the inserted USB plug 2. The upper resistive portion 531 makes the propping portion 534 uplift when the upper resistive portion 531 is pressed downwardly, and the propping portion 534 is also enable to raise the upper resistive portion 531 when the propping portion 534 is pressed downwardly. Furthermore, the upper resistive portion 531 and the lower resistive portion 532 constitute jointly the resilient element 530 of substantially split-ring shape. Therefore, the buckling component 53 which not only enhances the insertion and withdrawal force between the electrical connector 1 and the USB plug 2, but also prolongs usage life of the electrical connector 1.
The foregoing description of the present invention has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed, and obviously many modifications and variations are possible in light of the above teaching. Such modifications and variations that may be apparent to those skilled in the art are intended to be included within the scope of this invention as defined by the accompanying claims.
Number | Name | Date | Kind |
---|---|---|---|
5637015 | Tan et al. | Jun 1997 | A |
5738544 | Davis | Apr 1998 | A |
6386918 | Zheng et al. | May 2002 | B1 |
6682368 | Murr et al. | Jan 2004 | B2 |
20090042421 | Zheng et al. | Feb 2009 | A1 |