This Non-provisional application claims priority under 35 U.S.C. §119(a) on Patent Application No(s). 097129797 filed in Taiwan, Republic of China on Aug. 6, 2008, the entire contents of which are hereby incorporated by reference.
1. Field of the Invention
The invention relates to a stacked electrical connector and, more particularly, to a stacked electrical connector completely shielded.
2. Description of the Related Art
With the development of electronic science technology, more and more types of peripheral device of a computer are increased. The connection interfaces used by the devices having the same functions have a plurality of specification. Since shapes of a motherboard and a casing for containing the motherboard are limited, it is impossible to independently assemble all the connection interfaces at peripheries of the motherboard. Therefore, there are stacked connectors on the market. However, the present stacked electrical connector just makes separate connectors stacked together, and an area of pins for the motherboard is just a sum of areas of pins of the separate connectors. In addition, since the separate connectors are stacked, more part of signal transmission terminals (pins) is exposed to outside. That is, the signal interference may deteriorate. Particularly, the connector stacked above (away from the motherboard) is greatly affected.
Therefore, the conventional stacked electrical connector just saves a usable and limited periphery for the motherboard, and an area of a corresponding footprint configuration on the motherboard does not decrease in reality, which fails to benefit size decrease of the motherboard.
The objective of this invention is to provide a stacked electrical connector having a complete shielding function and suitable for a smaller area of a footprint configuration.
The invention provides a stacked electrical connector including a first connector, a second connector, and a conductive casing. The first connector includes a first signal connection portion and a first group of soldering pins extending along a direction. The second connector includes a second signal connection portion and a second group of soldering pins extending along the direction. The first connector is stacked on the second connector. The conductive casing has a first opening, a second opening, and a third opening. The conductive casing covers the first connector and the second connector. Thus, the first signal connection portion passes through the first opening, the second signal connection portion passes through the second opening, and the first group of soldering pins and the second group of soldering pins are exposed to the third opening. Thereby, the conductive casing can shield external interference, such that the electrical connector can still reliably transmit signals in the stacked structure.
The stacked electrical connector in an embodiment of the invention is applied to a video graphics array (VGA) connector and a digital visual interface (DVI) connector, and the VGA connector is closer to the third opening than the DVI connector. The soldering pins of the VGA connector may be arranged to two rows instead of conventional three rows, thus to decrease the thickness of the stacked electrical connector. In the embodiment, the whole thickness of the conductive casing vertical to the direction may be less than 12 mm.
Therefore, the stacked electrical connector in an embodiment of the invention has a complete shielding structure capable of effectively preventing electromagnetic interference. Further, by arranging the soldering pins properly, the thickness of the stacked electrical connector decreases, and the needed footprint configuration decreases, which benefits miniaturization of a circuit board connected with the connector.
These and other features, aspects, and advantages of the present invention will become better understood with regard to the following description, appended claims, and accompanying drawings.
The first connector 12 includes a first signal connection portion 122 and a first group of soldering pins 124 (one is marked). The first group of soldering pins 124 extends along a direction X. The second connector 14 includes a second signal connection portion 142 and a second group of soldering pins 144 (one is marked). The second group of soldering pins 144 also extends along the direction X. The conductive casing 18 has a first opening 182, a second opening 184, and a third opening 186, and it has a flat surface S parallel to the direction X. The first opening 182 and the second opening 184 are located at the flat surface S. The first signal connection portion 122 passes through the first opening 182, and a ground casing 126 of the first connector 12 contacts the conductive casing 18. The second signal connection portion 142 passes through the second opening 184, and a ground casing 146 of the second connector 14 also contacts the conductive casing 18. The first group of soldering pins 124 and the second group of soldering pins 144 are exposed to the third opening 186. In addition, the first connector 12 further includes two fastening posts 128 and two screw holes 130 corresponding to the fastening posts 128. The fastening post 128 includes a hexangular post 128a, a screw portion 128b, and a screw hole 128c (as shown in
Similarly, the second connector 14 further includes two fastening posts 148 and two screw holes 140 corresponding to the fastening posts 148. The fastening post 148 includes a hexangular post 148a, a screw portion 148b, and a screw hole 148c (as shown in
The outline of the first opening 182 matches the first signal connection portion 122, and the outline of the second opening 184 matches the second signal connection portion 124. Thereby, the conductive casing 18 can be attached to the first connector 12 and the second connector 14 to realize a complete cover, thereby providing a complete shielding function. In the preferred embodiment of the invention, without the conductive casing 18, under the external signal frequency from 115 MHz to 667 MHz, the stacked electrical connector 1 may suffer electromagnetic interference above than 10 dB. The highest electromagnetic interference suffered by the stacked electrical connector 1 having the conductive casing 18 under the same external signal frequency (even reaching to 983 MHz) is −2.6 dB. Apparently, the stacked electrical connector 1 in the embodiment of the invention can effectively solve the serious electromagnetic interference of the stacked electrical connector.
Please refer to
According to the preferred embodiment of the invention, the first connector 12 is a digital visual interface (DVI) connector, and the second connector 14 is a video graphics array (VGA0 connector. Please refer to
Please refer to
The first row of the connection points of the second signal connection portion 142 (the connection points marked from 1 to 5) corresponds to a first row of the holes 32 of the circuit board 3. The second row and the third row of the connection points (the connection points marked from 6 to 15) interlacingly correspond to a second row of the holes 32 of the circuit board 3. In other words, the second row (five soldering pins) of the second group of soldering pins 144 in
In another embodiment of the invention different from the above embodiment, the second group of soldering pins 144 electrically connected to the first and second row of the connection points of the second signal connection portion 142 (the connection points marked from 1 to 10) is integrated into one row. The second group of soldering pins 144 electrically connected to the third row of the connection points of the second signal connection portion 142 (the connection points marked from 11 to 15) directly forms another row. At that moment, the holes 32 of the circuit board 3 need to be correspondingly disposed. From the above, in the embodiment of the invention, the second group of soldering pins 144 corresponding to two adjacent rows of the connection points can be easily integrated into one row in a direct interlaced mode, thereby decreasing the area of the footprint configuration needed by the second group of soldering pins 144. Since the second group of soldering pins 144 is not averagely rearranged into two rows as a whole to correspond to the signal connection points (three rows), the manufacturing problem of the second connector 14 and the wiring problem of the circuit board 3 can be avoided.
Since the second connector 14 of the stacked electrical connector 1 needs a smaller footprint area, the stacked electrical connector 1 (or the conductive casing 18) has a thickness less than 12 mm along a direction vertical to the flat surface S (as shown in
To sum up, the stacked electrical connector in the invention has a complete shielding structure capable of effectively solving the serious electromagnetic interference caused by the stacked electrical connector. Further, by arranging the soldering pins to make them interlacingly correspond to the adjacent two rows of the signal connection points, the thickness of the stacked electrical connector decreases, and the needed footprint configuration decreases, which benefits miniaturization of a circuit board connected with the connector.
Although the present invention has been described in considerable detail with reference to certain preferred embodiments thereof, the disclosure is not for limiting the scope of the invention. Persons having ordinary skill in the art may make various modifications and changes without departing from the scope and spirit of the invention. Therefore, the scope of the appended claims should not be limited to the description of the preferred embodiments described above.
Number | Date | Country | Kind |
---|---|---|---|
097129797 | Aug 2008 | TW | national |