The invention relates to an alternating current (AC) power input socket, and more particularly to an AC power input socket that eliminates the need for an electric wire and a capacitor pin to be disposed at a same hole position of a conductive pin, thereby reducing the failure of inserting components into the hole position with certainty due to positional interference.
In the conventional alternating current (AC) power socket for transmitting power, a plurality of connecting terminals are disposed on one side of the socket, and at least one power cord is connected to the connecting terminals to transmit power during the implement.
In addition, in order to avoid electromagnetic interference (EMI) when transmitting power, the conventional AC power socket requires at least one capacitor to be connected between the connecting terminals. Disposition of the capacitor reduces the electromagnetic waves generated by the electromagnetic induction effect after the socket and the power cord are energized, thereby reducing the influence of electromagnetic interference on external devices or other electronic components. However, the conventional socket connects the power cord and the capacitor at a same hole position of the same connecting terminal. When the processing personnel processes the socket, the power cord or the capacitor has to be assembled on the connecting terminal first before soldering, and then the remaining capacitor or power cord is assembled and soldered. However, the solder is easily transformed into a molten state during the soldering process, the power cord will easily fall off during soldering of the capacitor, thus it is required for the processing personnel to fix the power cord and the capacitor at the same time in order to continue soldering. In addition, before soldering the capacitor or the power cord, one of them is required to be wound on the connecting terminal, and then soldered. In addition to increasing the working procedure, the one being wound interferes the latter to be disposed at the same hole position, and thus it is uncertain to be able to insert the latter into the hole position.
A main object of the invention is to solve the problem that the conventional socket welds the power cord and the capacitor at a same hole, causing interference of component positions and being unable to insert the components into the hole certainty.
In order to achieve the above object, the invention provides an alternating current (AC) power input socket. The AC power input socket includes a casing and at least two conductive pins. The casing defined with a connection side and an output side opposite to the connection side based on performance of the AC power input socket. The casing is provided with an accommodating groove at the connection side for inserting a plug. The two conductive pins are a live wire terminal and a ground wire terminal respectively, and each of the conductive pins includes a power connection section disposed in the accommodating groove, an output section which is extending from the power connection section and passing through the casing to be exposed on the output side, and a capacitor connecting section which is extending from an end of the output section. Each of the conductive pins is provided with a through hole in the output section for disposing an electric wire, and the capacitor connecting section provides a capacitor pin to be connected thereon.
In one embodiment, the AC power input socket includes three conductive pins, two of the three conductive pins are live wire terminals, and one of the three conductive pins is a ground wire terminal. Each of the three conductive pins includes the power connection section, the output section and the capacitor connecting section, and each of the conductive pins is provided with the through hole for disposing the electric wire in the output section, and the capacitor connecting section provides the capacitor pin to be connected thereon.
In one embodiment, each of the conductive pins includes a first width at the output section, and each of the conductive pins includes a second width smaller than the first width at the capacitor connecting section.
In one embodiment, each of the conductive pins is formed by two connecting pins which are respectively connected to the output section, and the two connecting pins are spaced apart to form a gap therebetween for the capacitor pin to pass through, and the two connecting pins respectively bear a force to be deformed to restrict the capacitor pin in the gap.
In one embodiment, each of the conductive pins includes a first width at the output section, and a sum of widths of the two connecting pins and the gap is smaller than the first width.
In one embodiment, the gap corresponds to a center of the through hole, and a sum of widths of the two connecting pins and the gap is greater than or equal to a width of the through hole
In one embodiment, a portion of each of the output sections which is close to the capacitor connecting sections is a slope.
In one embodiment, three longitudinal axis extension lines of the three conductive pins do not overlap, and two horizontal axis extension lines of two of the three conductive pins which are located on two sides overlap, and one horizontal axis extension line of one of the conductive pins which is located in a middle does not overlap with the other two horizontal axis extension lines.
In one embodiment, the AC power input socket is configured in a power supply unit.
Accordingly, compared with the conventional technique, the invention has the following features: the invention comprises the capacitor connecting section and the through hole provided on each of the conductive pins, so that the capacitor and the electric wire can be installed respectively on the capacitor connecting section and the through hole. Compared to the conventional technique, the capacitor and the electric wire of the invention do not need to be disposed at a same hole position, and therefore the situation that the component with a latter processing sequence cannot be connected on the conductive pin with certainty due to the interference of processing positions of the two components can be reduced.
The detailed description and technical content of the invention are described below with reference to the drawings.
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In addition, the AC power input socket 100 includes a casing 10 and at least two conductive pins 20, 30. The casing 10 is based on performance of the AC power input socket 100 to define a connection side 11 and an output side 12 which is opposite to the connection side 11. The casing 10 is provided with an accommodating groove 111 on the connection side 11 for inserting a plug, and the accommodating groove 111 corresponds to the plug in shape. In addition, the two conductive pins 20, 30 are respectively provided on the casing 10, one of the two conductive pins 20, 30 is a live wire terminal, and the other of the two conductive pins 20, 30 is a ground wire terminal. In this specification, the conductive pin 20 is implemented as the live wire terminal, and the conductive pin 30 is implemented as the ground wire terminal. Further, each of the conductive pins 20 (30) includes a power connection section 21 (31) disposed in the accommodating groove 111, an output section 22 (32) which is extending from the power connection section 21 (31) and passing through the casing 10, and a capacitor connecting section 23 (33) which is extending from an end of the output section 22 (32). In view of the two output sections 22, 32 and the two capacitor connecting sections 23, 33 are only seen when the AC power input socket 100 is viewed from a side, in consequence of the power connection section 21 (31) is disposed in the accommodating groove 111. In addition, each of the conductive pins 20 (30) is provided with a through hole 221 (321) in the output section 22 (32). In one embodiment, each of the through holes 221 (321) is an oval hole. For example, a longitudinal axis width of the through hole 221 (321) is greater than a horizontal axis width of the through hole 221 (321) in the invention.
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In one embodiment, the AC power input socket 100 further includes three conductive pins 20, 30, 40, two of the three conductive pins 20, 30, 40 are the live wire terminals, and one of the three conductive pins 20, 30, 40 is the ground wire terminal. In this specification, the two conductive pins 20, 40 are implemented as the live wire terminals, and the conductive pin 30 is implemented as the ground wire terminal. Moreover, each of the conductive pins 20 (or 30 or 40) includes a power connection section 21 (or 31 or 41), a output section 22 (or 32 or 42), and a capacitor connecting section 23 (or 33 or 43) respectively, and each of the conductive pins 20 (or 30 or 40) is provided with a through hole 221 (or 321 or 421) in a output section 22 (or 32 or 42).
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In one embodiment, configurations of the three conductive pins 20, 30, 40 of the invention are the same, and one of the three conductive pins 20 is used for explanation hereinafter in order for the convenience of description. Please refer to
The conductive pin 20 of the invention includes a first width 222 at the output section 22, and a second width 233 at the capacitor connecting section 23, wherein the second width 233 is smaller than the first width 222. In other words, a sum of widths of the gap 232 and the two connecting pins 231 is smaller than a width of the output section 22. Furthermore, a sum of the widths of the gap 232 and the two connecting pins 231 is greater or equal to a width of the through hole 221. In one embodiment, the through hole 221 of the invention includes a center line 223, and the gap 232 diverges from the center line 223. On the other hand, in this embodiment, a portion of one side of the output section 22 is a curved surface 224.
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Number | Date | Country | Kind |
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108132356 | Sep 2019 | TW | national |