1. Field of the Invention
The present invention relates to USB connectors and more particularly, to such a USB connector, which has a rear cover fastened to the rear side of the first connection port and the top side of the bottom positioning member to shield the first and second conducting terminals, the adapter terminals and the circuit module, prohibiting them from contacting the outer metal shield to cause a short circuit.
2. Description of the Related Art
Following fast development of modern electronic technology, many different advanced and small-sized electronic devices have been intensively used in our daily life. Nowadays, many people use notebook computer instead of desk computer for the advantage of high mobility. Further, different interface devices shall be used for data and/or signal transmission between a host and different peripheral apparatus, or among different electronic devices. USB (Universal Serial Bus) interface devices are most popularly used interface devices for the advantage of hot-plug capabilities.
An early design of USB 2.0 standard (USB Hi-Speed) improves the transmission speed from 12 Mbps up to 480 Mbps. However, this design can simply be used in a peripheral apparatus (such as card reader, printer, memory stick, network phone, and network camera) of low driving power. Nowadays, these data transmission speeds cannot satisfy the demand for quick transmission of a big amount of data within a limited time, i.e., USB2.0 cannot be used with a high capacity hard disk drive or DVD copier, DVD player or any advanced blue light electronic device. In consequence, high speed data transmission connectors have been continuously created. For example, USB 3.0 standard (USB Super-Speed) provides a transmission speed as high as 4.8 Gbps. In consideration of compatibility to conventional USB 2.0, USB 3.0 maintains the original conducting terminals and adds an extra set of conducting terminals, i.e. a USB 3.0 connector has two sets of conducting terminals arranged therein to support two-way transmission at a high speed. The enhanced power supplying capability of USB 3.0 standard allows the use of a detachable high-capacity hard disk drive without extra power supply, and also permits connection of extra peripheral apparatus.
Based on the design of the aforesaid USB2.0 female connector, extra conducting terminals may be installed in the connector body A to constitute a USB3.0 female connector. However, due to limited internal space, it is difficult to install an extra row of conducting terminals in the connector body A. Further, when a big number of conducting terminals are installed in the connector body A, signal transmission interference may occur, lowering the signal transmission quality and increasing the risk of electromagnetic interference. Further, after installation, the upper row of conducting terminals B and the bottom row of conducting terminals C may touch the metal shield D accidentally, causing a short circuit and increasing product defective rate.
Therefore, it is desirable to provide a USB connector, which eliminates the drawbacks of conventional USB2.0 multi-port connectors.
The present invention has been accomplished under the circumstances in view. Therefore, it is the main object of the present invention to provide a USB connector, which has an electrically insulative rear cover fastened to the rear side of the first connection port and the top side of the connection member of bottom positioning member to shield the rear bonding portions of the first conducting terminals and second conducting terminals, the adapter terminals and the circuit module and to prohibit them from contacting the outer metal shield to cause a short circuit. Further, the rear cover has a plurality of locating flanges respectively from the front side and bottom sides thereof and respectively engaged into a receiving chamber and locating grooves of the connector body, assuring installation stability.
Further, the adapter board of the circuit module of the USB connector comprises two rows of first metal contacts and second metal contact for the bonding of the connection portions of the metal connection terminals and the connection portions of the adapter terminals respectively by means of surface mount technology so that the surface space of the adapter board can be fully utilized for the installation of electronic components to maintain their electric properties for best performance.
Further, the first connection port has the bottom side thereof mounted with a bottom positioning member. In an alternate form of the invention, the USB connector comprises a first connection port and a second connection port defined in the connector body thereof, a bottom positioning member located on the bottom side of the second connection port, a connection block located on the rear side of the bottom positioning member, and a metal shield surrounding the connector body for grounding. The first and second conducting terminals of the first and second connection ports and the metal connection terminals held in the connection block are well shield and isolated, avoiding electromagnetic interference. The electrically insulative component parts are conveniently fastened by hooking, assuring high connection stability for plugging and unplugging of an external USB connector.
Further, electronic components are installed in the adapter board. The adapter board comprises a set of first contacts and a set of second contact for the bonding of the rear bonding portion of the first conducting terminals and second conducting terminals of the first connection port and the rear bonding portion of the first conducting terminals and second conducting terminals of the second connection port respectively, and a set of first metal pads and a set of second metal pads respectively arranged at the rear side thereof corresponding to the electronic components. The electronic components include filter devices that can be CMC (common mode chokes), filter resistors and/or filter capacitors, and protection devices that can be TVS (transient voltage suppressor and/or varistor for protection against surge and/or static electricity. Thus, the electronic components of the adapter board effectively remove noises, electromagnetic interference, transient voltage, surge or static electricity during signal transmission, assuring signal transmission quality and reliability and avoiding signal interrogation or signal transmission failure.
Referring to
The connector body 1 comprises a first connection port 11 and a bottom positioning member 12 fastened to the bottom side of the first connection port 11. The first connection port 11 comprises a forwardly extending tongue plate 111 having multiple bottom terminal grooves 1111, a set of first conducting terminals 112 mounted in the top side of the tongue plate 111, a set of second conducting terminals 113 mounted in the bottom terminal grooves 1111 of the tongue plate 111. The first conducting terminals 112 and second conducting terminals 113 have the respective front contact portions 1121 or 1131 suspending below the tongue plate 111 and arranged in two rows and the respective rear bonding portions 1122 or 1132 extending out of the rear side of the first connection port 11. The first connection port 11 further comprises a plurality of bottom hooks 114 and bottom mounting rods 115. The bottom positioning member 12 comprises a plurality of retaining blocks 121 and retaining holes 122 disposed at the top side thereof, multiple terminal slots 123 vertically cut through the top and bottom sides near the rear side thereof and holding a set of adapter terminals 124. Each adapter terminal 124 has one end terminating in a connection portion 1241 and the other end terminating in a bonding portion 1242.
The circuit module 2 comprises an adapter board 21 carrying a circuit layout, and a plurality of electronic components 22 installed in the adapter board 21. The electronic components 22 include filter devices 221 that can be CMC (common mode chokes), filter resistors and/or filter capacitors, and protection devices 222 that can be TVS (transient voltage suppressor and/or varistor for protection against surge and/or static electricity. According to this embodiment, 6 filter devices 221 are arranged in two rows on the front side of the adapter board 21; 3 protection devices 222 are arranged in a row and spaced between the two rows of filter devices 221. The adapter board 21 comprises a set of first contacts 211 and a set of second contacts 212 respectively arranged in a row above one respective row of filter devices 221 for the bonding of the rear bonding portion 1122;1132 of the first conducting terminals 112 and second conducting terminals 113 of the first connection port 11 respectively, and a set of first metal pads 213 arranged at the rear side thereof corresponding to the electronic components 22. The connection portions 1241 of the adapter terminals 124 are respectively bonded to the first metal pads 213 of the adapter board 21.
The metal shield 4 surrounds the connector body 1 and the circuit module 2, defining a front insertion hole 44 for receiving an external USB connector.
During installation, the rear bonding portion 1122;1132 of the first conducting terminals 112 and second conducting terminals 113 of the first connection port 11 are respectively electrically bonded to the first contacts 211 of the adapter board 21, and then the bottom hooks 114 and bottom mounting rods 115 of the first connection port 11 are respectively fastened to the respective retaining blocks 121 and retaining holes 122 of the bottom positioning member 12. Thus, the first connection port 11 and the bottom positioning member 12 are fastened together. Thereafter, the connection portions 1241 of the adapter terminals 124 are respectively bonded to the first metal pads 213 of the adapter board 21 by SMT (surface mount technology). At final, fasten the metal shield 4 to the outside wall of the connector body 1, finishing the assembly process of the USB 3.0 connector.
The connector body 1 comprises an electrically insulative base member 13, a first connection port 11 and a second connection port 14 respectively arranged at the top and bottom sides of the electrically insulative base member 13 and a bottom positioning member 12 arranged at the bottom side of the second connection port 14. According to this embodiment, the electrically insulative base member 13 comprises a plurality of retaining blocks 131 and retaining holes 132 disposed at the top side thereof, a plurality of bottom hooks 133 and bottom mounting rods 134 located on the bottom side thereof.
The first connection port 11 comprises a forwardly extending tongue plate 111 having multiple bottom terminal grooves 1111, a set of first conducting terminals 112 and a set of second conducting terminals 113 mounted in the top and bottom sides of the tongue plate 111 in a parallel manner. The second conducting terminals 113 are respectively positioned in the bottom terminal grooves 1111 of the tongue plate 111. The first conducting terminals 112 and the second conducting terminals 113 each have a front contact portion 1121 or 1131 suspending below the tongue plate 111, and a rear bonding portion 1122 or 1132 extending out of the rear side of the first connection port 11. The first connection port 11 further comprises a plurality of bottom hooks 115 and bottom mounting rods 116. The first conducting terminals 113 and second conducting terminals 114 of the first connection port 11 each have a front contact portion 1131 or 1141 suspending below the tongue plate 111, and a rear bonding portion 1132 or 1142 extending out of the rear side of the first connection port 11. The second connection port 14 comprises a forwardly extending tongue plate 141 having multiple bottom terminal grooves 1411, and a set of first conducting terminals 142 and a set of second conducting terminals 143 mounted in the top and bottom sides of the tongue plate 141 in a parallel manner. The second conducting terminals 143 are respectively positioned in the bottom terminal grooves 1411 of the tongue plate 141. The first conducting terminals 142 and the second conducting terminals 134 each have a front contact portion 1421 or 1431 suspending below the tongue plate 141, and a rear bonding portion 1422 or 1432 extending out of the rear side of the second connection port 14. The second connection port 14 further comprises a plurality of retaining blocks 144 and retaining holes 145 disposed at the top side and a plurality of bottom hooks 146 and bottom mounting rods 147 disposed at the bottom side.
The circuit module 2 comprises an adapter board 21 carrying a circuit layout, and a plurality of electronic components 22 installed in the adapter board 21. The adapter board 21 comprises a set of first contacts 211 and a set of second contacts 212 respectively arranged in a row above one respective row of filter devices 221 for the bonding of the rear bonding portion 1122;1132 of the first conducting terminals 112 and second conducting terminals 113 of the first connection port 11 and the rear bonding portion 1422;1432 of the first conducting terminals 142 and second conducting terminals 143 of the second connection port 14 respectively, and a set of first metal pads 213 and a set of second metal pads 214 respectively arranged at the rear side thereof corresponding to the electronic components 22.
The connection block 3 comprises a plurality of terminal slots 31 vertically extending through top and bottom sides thereof, and a plurality of locating grooves 33 located on the top side thereof and respectively extended from the top ends of the terminal slots 31. Further, metal connection terminals 32 are respectively mounted in the terminal slots 31. Each metal connection terminal 32 has a connection portion 321 located on its one end and a bonding portion 322 located on its other end, and a curved middle portion 323 connected between the connection portion 321 and the bonding portion 322. The bonding portions 322 of the metal connection terminals 32 extend out of the terminal slots 31 for bonding to an external circuit board. The curved middle portions 323 of the metal connection terminals 32 are respectively positioned in the locating grooves 33.
The metal shield 4 includes a front frame shell 41, a rear cover shell 42 and an internal clamping shell 43. The front frame shell 41 and the rear cover shell 42 are fastened together and covered over the connector body 1. The internal clamping shell 43 is clamped on the electrically insulative base member 13 of the connector body 1, and stopped against spring lugs 411 of the front frame shell 41. Further, the internal clamping shell 43 divides the internal space of the front frame shell 41 into two insertion holes 40 for receiving one respective external USB connector.
When assembling the first connection port 11 and second connection port 14 of the connector body 1 with the insulative base member 13 and the bottom positioning member 12, the bottom hooks 115 of the first connection port 11 and the bottom mounting rods 147 of the second connection port 14 are respectively engaged into the retaining holes 122 of the bottom positioning member 12 and the retaining holes 132 of the electrically insulative base member 13.
During installation, as shown in
Thereafter, bond the rear bonding portions 1122;1232 of the first conducting terminals 112 and second conducting terminals 113 of the first connection port 11 electrically to the first contacts 211 of the adapter board 21, and then bond the rear bonding portions 1422;1432 of the first conducting terminals 142 and second conducting terminals 143 of the second connection port 14 electrically to the second contacts 212 of the adapter board 21, and then force the bottom hooks 146 of the second connection port 14 into engagement with the retaining holes 121 of the bottom positioning member 12 to have the bottom mounting rods 147 of the second the second connection port 14 be respectively fitted into the retaining holes 122 of the bottom positioning member 12. Thus, the second connection port 14 and the bottom positioning member 12 are connected together. Thereafter, bond the connection portions 1241 of the adapter terminals 124 of the bottom positioning member 12 to the first metal pads 213 of the adapter board 21 by surface mount technology, and then attach the connection block 3 to the rear side of the bottom positioning member 12 to let the bonding portions 322 of the metal connection terminals 32 be inserted through respective vertical terminal slots 123 of the bottom positioning member 12, and then bond the connection portions 321 of the metal connection terminals 32 to the second metal pads 214 of the adapter board 21 by surface mount technology, and then mount the metal shield 4 around the connector body 1 to keep the first connection port 11 and the second connection port 14 in the insertion holes 40. Thus, the USB 3.0 connector is assembled.
Referring to
During application of the present invention, an external USB connector is inserted into one insertion hole 40 of the metal shield 4 and attached to the first connection port 11 or second connection port 12. At this time, the inserted external USB connector is electrically connected to the first conducting terminals 112 and second conducting terminals 113 of the first connection port 11 or the first conducting terminals 142 and second conducting terminals 143 of the second connection port 12 for two-way signal transmission. Thus, external signals can be transmitted through the first conducting terminals 112;142 and second conducting terminals 113;143 of the first and second connection ports 11;14 to the first contacts 211 of the adapter board 21 and the second conducting terminals 143, enabling the electronic components 22 to remove the unnecessary noises and electromagnetic interference. After filtration by the electronic components 22, the signal is transmitted through the first metal pads 213 or second metal pads 214, the adapter terminals 124 or metal connection terminals 32 to the microprocessor, control chip or control IC of the circuit board for signal conversion and serial data output. Thus, the electronic components 22 of the adapter board 21 effectively remove noises, electromagnetic interference, transient voltage, surge or static electricity during signal transmission, assuring signal transmission quality and reliability and avoiding signal interrogation or signal transmission failure.
The aforesaid embodiment is simply an example of the present invention but not intended as a limitation. The adapter board 21 has electronic components 22 connected between its signal input ends and its signal output ends. The circuit arrangement of the embodiment in which the connector body 1 simply comprises one first connection port 11 is same as the circuit arrangement of the embodiment in which the connector body 1 comprises one first connection port 11 and one second connection port 14. Thus, the circuit arrangement of the embodiment in which the connector body 1 comprises one first connection port 11 and one second connection port 14 is explained hereinafter for understanding. The adapter board 21 has 18 signal input ends. These 18 signal input ends are respectively electrically connected to the metal connection terminals 32 and the adapter terminals 124 through the first metal pads 213 and second metal pads 214 of the adapter board 21. Further, the adapter board 21 has 18 signal output ends for signal output. These 18 signal output ends are respectively electrically connected to the first conducting terminals 112;142 and second conducting terminals 113;143 of the first and second connection ports 11;14 through the first contacts 212 and second contacts 212 of the adapter board 21. In the first conducting terminals 112;142, a grounding terminal (GND_DRAIN) is set in between each of the two pairs of signal terminals (StdA_SSRX−;StdA_SSRX+ and StdA_SSTX−;StdA_SSTX+). In the second conducting terminals 113;143, a power terminal (VBUS) and a power grounding terminal (GND) are respectively arranged at the left and right sides of the pair of signal terminals (D− and D+).
Further, the electronic components 22 include filter devices 221 that can be CMC (common mode choke), filter resistor and/or filter capacitor, and protection devices 222 that can be TVS (transient voltage suppressor) and/or varistor for protection against surge and/or static electricity. According to this embodiment, 6 filter devices 221 are arranged in two rows and electrically connected between the signal input ends and signal output ends of the adapter board 21, i.e., the 6 filter devices 221 are electrically connected between the signal input ends and signal output ends of the adapter board 21 to which the signal terminals (StdA_SSRX−, StdA_SSRX+, StdA_SSTX−, StdA_SSTX+, D− and D+) of the first conducting terminals 112;142 and the second conducting terminals 113;143 are electrically connected.
Further, 3 protection devices 222 are electrically connected in parallel to the filter devices 221 between the signal input ends and signal output ends of the adapter board 21 to which the signal terminals (StdA_SSRX−, StdA_SSRX+, GND_DRAIN, StdA_SSTX−, StdA_SSTX+) of the second conducting terminals 113;143 are electrically connected. The signal input ends and signal output ends of the adapter board 21 to which the power terminals (VBUS) of the second conducting terminals 113;143 are electrically connected are respectively electrically connected to one pin of each of the protection devices 222. The signal input ends and signal output ends of the adapter board 21 to which the power grounding terminals (GND) of the second conducting terminals 113;143 are electrically connected are respectively electrically connected to the other pin of each of the protection devices 222. The number and/or specifications of the electronic components 22 may be changed subject to different requirements. Thus, an external signal can be transmitted through the first conducting terminals 112 and second conducting terminals 113 of the first connection port 11 or the first conducting terminals 142 and second conducting terminals 143 of the second connection port 14 to the electronic components 22, enabling the electronic components 22 to remove noises, electromagnetic interference, transient voltage, surge or static electricity, assuring signal transmission quality and reliability and avoiding signal interrogation or signal transmission failure.
Referring to
When connecting the first conducting terminals 112 and second conducting terminals 113 of the first connection port 11 and the first conducting terminals 142 and second conducting terminals 143 of the second connection port 14 to the adapter board 21 of the circuit module 2, the first contacts 211 and the second contacts 212 can be respectively arranged in two rows with 5 contacts at the top side and the other 4 contacts at the bottom side in a staggered manner. Alternatively, the second contacts 212 can be arranged in a rectangular array below the first contacts 211 wherein the signal terminals (D_, D+) of the second conducting terminals 113;143 are downwardly arranged between the signal terminal (StdA_SSTX+) and signal grounding terminal of the first conducting terminals 112;142; the power terminal (VBUS) and power grounding terminal (GND) of the second conducting terminals 113;143 are downwardly arranged between the signal terminal (StdA_SSRX−) and signal grounding terminal of the first conducting terminals 112;142. Further, a power grounding terminal (DGND) may be respectively arranged blow the space between the signal terminals (StdA_SSTX−, StdA_SSTX+) of the first conducting terminals 112;142, and a power terminal (DPWR) may be respectively arranged blow the space between the signal terminals (StdA_SSRX−, StdA_SSRX+) of the first conducting terminals 112;142, The power grounding terminals (DGND) and the power terminals (DPWR) are respectively set in alignment between the signal terminals (D−, D+) of the second conducting terminals 113;143, or between the power terminal (VBUS) and the power grounding terminal (GND). Other equivalent alternations may be adopted to meet USB 3.0 standards without departing from the spirit and scope of the invention.
Referring to
Referring to
While only certain embodiments of the present invention have been described in detail for purposes of illustration various modifications and enhancements may be made thereunto without departing from the spirit and scope of the invention. Accordingly, the invention is not to be limited except as by the appended claims.
Number | Name | Date | Kind |
---|---|---|---|
8038474 | Ju | Oct 2011 | B2 |
20100261385 | Zheng et al. | Oct 2010 | A1 |
20110130036 | Ju | Jun 2011 | A9 |
20110195601 | Chen et al. | Aug 2011 | A1 |