A plug connector in accordance with the present invention complies with USB 2.0 and USB 3.0 specifications.
A Universal Serial Bus (USB) is a serial bus standard to interface devices with a host computer. The USB was designed to allow many computer peripherals to be connected using a single standardized interface socket and to improve plug and play capabilities by allowing devices to be connected and disconnected without rebooting the computer and turning off the device.
Other convenient features of the USB include providing power to low-consumption devices without a separate external power supply and allowing many devices to be used without requiring manufacturer specific individual device drivers to be installed.
The USB is intended to substitude for serial ports and parallel ports and connects many computer peripherals such as mice, keyboards, PDAs, gamepads, joysticks, scanners, digital cameras, printers, personal media players and flash drives. For many of those devices, the USB has become a standard connection.
USB 2.0 is the most popular USB specification and supports high speed data transmission up to 480 Mbps. However, a more reliable connection technique with a higher transmission rate allows modern digital equipment to transmit greater amounts of data and operate closer to real-time. A USB 3.0 specification was developed to provide a higher data transfer rate than the USB 2.0 specification.
The USB 3.0 data transfer rate (4.8 Gbps) is ten times the USB 2.0 data transfer rate. The USB 3.0 specification is expected to upgrade data transfer efficiency of personal computers, consumer electronics and mobile devices but is not commonly used, yet. The USB 2.0 specification is the dominant USB specification. If the USB 2.0 and USB 3.0 specifications could be combined to form a new interface, the interface would have to comply with the USB 2.0 and USB 3.0 specifications and could be used simultaneously to meet consumers' current and emerging demands.
The objective of the present invention is to provide a plug connector that complies with USB 2.0 and 3.0 specifications.
A plug connector in accordance with the present invention comprises a first subassembly, a second subassembly and a casing. The first subassembly comprises a mounting frame and four first contact pins. The first contact pins comply with the USB 2.0 specification and are insert-molded in the mounting frame to form the first subassembly. The second subassembly is combined with the first subassembly and comprises a mounting frame and five second contact pins. The second contact pins comply with the USB 3.0 specification, are mounted in the mounting frame to form the second subassembly and are staggered with the first contact pins after the first subassembly and second subassembly are combined. The casing covers the first subassembly and the second subassembly.
With reference to
The first subassembly (1) comprises a mounting frame (11) and four first contact pins (12).
With further reference to
The first contact pins (12) comply with a USB 2.0 specification, are insert-molded in the mounting frame (11) and comprise two central first contact pins (12A) and two outer first contact pins (12B).
The central first contact pins (12A) are U-shaped. Each central first contact pin (12A) has an upper surface, a lower surface, a longitudinal shaft, an offset socket contact (121A), and an offset wire contact (122A).
The longitudinal shaft has a front end and a rear end.
The offset socket contact (121A) is formed on the front end of the longitudinal shaft, protrudes transversely from the upper surface, bends, protrudes longitudinally from the longitudinal shaft, is mounted on the front recess (111) to connect to a video port connector and has an optional curved tip (123A). The curved tip (123A) is bent downward to embed in the front recess (111) to prevent the first contact pins (12A) from bending upward.
The offset wire contact (122A) is formed on the rear end of the longitudinal shaft, protrudes transversely from the upper surface, bends, protrudes longitudinally from the longitudinal shaft, is mounted on a corresponding recessed slot (116) on the outer surface, has nonskid on the upper and lower surfaces and connects to corresponding wires from a device to which the plug connector is connected. The nonskid on the two central first contact pins (12A) expands outward.
The outer first contact pins (12B) are U-shaped and are slightly longer than the central first contact pins (12A). Each outer first contact pin (12B) has an upper surface, a lower surface, a longitudinal shaft, an offset socket contact (121B), and an offset wire contact (122B).
The longitudinal shaft has a front end and a rear end.
The offset socket contact (121B) is formed on the front end of the longitudinal shaft, protrudes transversely from the upper surface, bends, protrudes longitudinally from the longitudinal shaft, is mounted on the front recess (111) to connect to a video port connector and has an optional curved tip (123B). The curved tip (123B) is bent downward to embed in the front recess (111) to prevent the outer first contact pins (12B) from bending upward.
The offset wire contact (122B) is formed on the rear end of the longitudinal shaft, protrudes transversely from the upper surface, bends, protrudes longitudinally from the longitudinal shaft, is mounted on a corresponding recessed slot (116) on the outer surface, has nonskid on the upper and lower surfaces and connects to corresponding wires from a device to which the plug connector is connected. The nonskid on the two outer first contact pins (12B) expands toward the central first contact pins (12A) to decrease distances between the nonskid of the four first contact pins (12) to keep the wires connecting respectively to the first contact pins (12) from separating to maintain efficiency of high frequency transmission.
The second subassembly (2) is connected to the first subassembly (1) and comprises a mounting frame (21) and five second contact pins (22).
The mounting frame (21) is an insulator and has a front end, a rear end, an outer surface, an inner surface, five contact pin seats (211), multiple anchor holes (212) and an optional detent (213). The contact pin seats (211) are formed on the inner surface. The anchor holes (212) are formed on the inner surface near the rear end and hold the anchor protrusions (115) to connect the first subassembly (1) and the second subassembly (2). The detent (213) is formed on the outer surface and front end.
The second contact pins (22) comply with a USB 3.0 specification, are mounted respectively in the contact pin seats (211) of the mounting frame (21) to form the second subassembly (2), are staggered with the first contact pins (12) and comprise one central second contact pin (22A) and four outer second contact pins (22B), and each second contact pin (22) has a front end, a resilient contact (221), a rear end, a protrusion (222), an upper nonskid surface (223). The front end is a hook and includes an upper surface and a lower surface. The resilient contact (221) is formed on the upper surface of the front end to connect to a video port connector. The rear end includes an upper surface and a lower surface and is on the rear recess (113) by the lower surface after the first subassembly (1) and the second subassembly (2) are connected. The protrusion (222) extends upward between the front and rear ends and is held in place by a corresponding second contact pin support (114) to prevent the second contact pin (22) from moving. The upper nonskid surface (223) is formed adjacent to the rear end. The upper nonskid surface (223) on the central second contact pin (22A) is linear. The upper nonskid surfaces (223) of the four outer second contact pins (22B) bend toward the central second contact pin (22A) to decrease distances between the upper nonskid surfaces (223) of the five second contact pins (22) to keep cables from separating and to maintain efficiency of high frequency transmission.
The casing (3) covers the first subassembly (1) and the second subassembly (2) and comprises an inner surface, an outer surface and an optional boss (31). The boss (31) is formed on the inner surface to press against the optional detent (213) to keep the assembled first subassembly (1) and the second subassembly (2) mounted correctly in the casing (3).
Number | Name | Date | Kind |
---|---|---|---|
6309255 | Yu | Oct 2001 | B1 |
7128617 | Wang et al. | Oct 2006 | B2 |
7155545 | Wang | Dec 2006 | B1 |
7232346 | Hu et al. | Jun 2007 | B2 |
7354314 | Sprouse et al. | Apr 2008 | B1 |