Abstract: A method for fabricating a magnesium-based alloy includes the steps of: (a) mixing a number of carbon nanotubes with a number of magnesium particles; (b) heating the mixture in a protective gas to achieve a semi-solid-state paste; (c) stirring the semi-solid-paste using an electromagnetic stirring force to disperse the carbon nanotubes into the paste; (d) injecting the semi-solid-state paste into a die; and (e) cooling the semi-solid-state paste to achieve a magnesium-based alloy. An apparatus for fabricating the magnesium-based alloy includes a transferring device, a thixomolding machine, and an electromagnetic stirring device. The transferring device includes a feed inlet. The thixomolding machine includes a heating barrel having two ends, a nozzle disposed at a first end thereof, and an material input positioned at a second end thereof. The electromagnetic stirring device includes an electromagnetic induction coil disposed on an outer wall of the heating barrel.

Abstract: A mounting apparatus is used to secure a disk drive, which defines a mounting hole therein. The mounting apparatus includes a bracket and a mounting member. The bracket is configured for receiving the disk drive therein. A through hole is defined in the bracket. A locking tab is formed on the bracket. The mounting member includes two arms and an operating portion. One end of each of the arms is pivotably secured on the bracket so that the mounting member is pivotable relative to the bracket, and the other end thereof connects with the operating portion. A positioning portion is formed on the operating member. The operating portion is capable of engaging with the locking tab of the bracket for inserting the positioning portion into the mounting hole of the disk drive via the through hole of the bracket.

Abstract: An apparatus includes a computer chassis and a motherboard. The motherboard defines a rotating hole, a clasp hole, and a through hole. The clasp hole has a clasp slot and an arcuate groove. The computer chassis includes a bottom plate, and a first, second, and third convex projections. A rotating shaft is formed on the first convex projection. A mounting hole is defined in the second convex projection. A clasp is formed on the third convex projection. The clasp includes a root connected with the third convex projection, and a bent portion. The motherboard is rotatable between a first and a second position. In the first position, the rotating shaft of the first convex projection is inserted in the rotating hole, and the bent portion of the clasp extends through the clasp slot. In the second position, the root of the clasp is located in the arcuate groove, and the though hole of the motherboard is aligned with the mounting hole of the second convex projection.

Abstract: A Voice over Internet Protocol (VoIP) system includes two or more VoIP terminals, a monitoring server (30), and a soft switch device (10). The soft switch is capable of determining whether or not phone number associated with at least one of the two or more VoIP terminals is predetermined to be monitored, amending information associated with communication between the two or more VoIP terminals, and establishing the communication between the two or more VoIP terminals through the monitoring server. The monitoring server is capable of reading voice data packets sent between the two or more VoIP terminals.

Abstract: A circuit includes a work-power module, an electronic component, a switching apparatus, and a power control unit. The power control unit includes an input pin connected to the work-power module, an output pin connected to the electronic component, and a control pin connected to the switching apparatus. The switching apparatus is capable of controlling the status of the power control unit. Upon the condition that the power control unit is turned on, the work-power module is capable of supplying power to the electronic component. Upon the condition that the power control unit is turned off, the work-power module is not capable of supplying power to the electronic component.

Abstract: An exemplary method for forming gaps in a micromechanical device includes providing a substrate. A first material layer is deposited over the substrate. A sacrificial layer is deposited over the first material layer. A second material layer is deposited over the sacrificial layer such that at least a portion of the sacrificial layer is exposed. The exposed portion of the sacrificial layer is etched by dry etching. The remaining portion of the sacrificial layer is etched by wet etching to form gaps between the first material layer and the second material layer. One or more bulges are formed at one side of the second material layer facing the first material layer, and are a portion of the sacrificial layer remaining after the wet etching.

Abstract: A demagnetization circuit for reducing interference in a mobile phone includes a wave filter, a demagnetization circuit and an audio playing circuit. The wave filter is configured to filter a received audio signal from the mobile phone. The wave filter includes an input that receives the audio signal, and an output. The demagnetization circuit is structured and arranged to generate an opposite magnetic field to that of the mobile phone to reduce pulse magnetic fields generated by the mobile phone.

Abstract: A cover locking structure (100) for portable electronic device includes a housing (20), a releasable member (30) and a cover (10). The housing includes an end wall (22) and an extending wall (26). The end wall defines an opening (222) defined therein. One end of the extending wall connects with the end wall. The extending wall has a locking hole (2642) defined therein. The releasable member is flexibly fixed on the housing and has a block (3242) formed thereon. The block corresponds to the locking hole of the extending wall. The cover has a hook (14) formed thereon. The hook is locked in the locking hole when the cover is assembled to the housing. The block of the releasable member pushes the hook out off the locking hole when the cover is to be detached from the housing.

Abstract: A method for manufacturing a carbon nanotube composite, comprising the steps of:(a) preparing a solution of a polymer precursor; (b) immersing carbon nanotubes in the solution and ultrasonically cleaning the solution; (c) polymerizing the polymer precursor in order to obtain a polymer matrix having carbon nanotubes uniformly dispersed therein; (d) forming the polymer matrix into a composite having carbon nanotubes distributed therein by way of extrusion; and (e) elongating the composite so as to cause the carbon nanotubes to be orderly distributed therein.

Abstract: A chip card retaining mechanism includes a first holding frame, a second holding frame and a circuitry. The first holding frame includes a latching portion and a connecting board. The latching portion defines a first receiving room for receiving a first chip card. The second holding frame is attached to the connecting board of the first holding frame, and is perpendicular to the latching portion of the first holding frame. The second holding frame defines a second receiving room for receiving a second chip card. The circuitry is formed on the connecting board and the latching portion. The first chip card is electronically connected to the second chip card via the circuitry.

Abstract: An equalizer includes a first resistor and a capacitor connected in parallel. The positive terminal of the capacitor is connected to a signal transmission line on a blah printed circuit board. The negative terminal of the capacitor is connected to ground through a second resistor. A connector including the equalizer and a printed circuit board including the connector are also provided.

Abstract: A testing system includes a computer (10), a motherboard (31) of a mobile phone, a photosensitive component (33) and a measuring device. The motherboard of the mobile phone is connected to the computer. The motherboard of the mobile phone includes a keyboard light (313) disposed thereon. The photosensitive component is capable of sensing the brightness of the keyboard light. The measuring device is connected to the photosensitive component. The measuring device is capable of measuring the resistance of the photosensitive component and transmitting the resistance to the computer. The computer is capable of comparing the resistance with a pre-determined range of values to determine whether the keyboard light of the motherboard meets a standard.

Abstract: An exemplary refractive-index sensor includes a photonic crystal microcavity structure, a light source, and a detector. The photonic crystal microcavity structure includes a photonic crystal layer having first holes and a second hole. The first holes are arranged in a pattern of staggered parallel rows. The second hole is located at an approximate center point of the middle row of the pattern rather than a first hole. A diameter of the second hole is less than that of each of the first holes. Some of the first holes disposed at each of opposite ends of a diagonal row having the second hole are omitted to define an input waveguide and an output waveguide. The light source is adjacent to the input waveguide. The detector is adjacent to the output waveguide.

Abstract: A thermionic emission device includes an insulating substrate, and one or more grids located thereon. Each grid includes a first, second, third and fourth electrode down-leads located on the periphery thereof, and a thermionic electron emission unit therein. The first and second electrode down-leads are parallel to each other. The third and fourth electrode down-leads are parallel to each other. The first and second electrode down-leads are insulated from the third and fourth electrode down-leads. The thermionic electron emission unit includes a first electrode, a second electrode, and a thermionic electron emitter. The first electrode and the second electrode are separately located and electrically connected to the first electrode down-lead and the third electrode down-lead respectively. The insulating substrate comprises one or more recesses that further insulate the thermionic electron emitters from the substrate.

Abstract: A diode includes an organic composite plate, a pressing element, a first electrode, and a second electrode. The organic composite plate has a plurality of carbon nanotubes uniformly distributed therein and includes a first portion and a second portion opposite to the first portion. The pressing element is disposed on the first portion of the organic composite plate. The first and second electrodes are electrically connected to the first and second portions of the organic composite plate, respectively. The diode employed with the carbon nanotubes has a changeable characteristic, such as voltage, current, via controlling the pressure applied by the pressing element.

Abstract: An electronic apparatus includes an enclosure (30), a circuit board (40), a fan module (20), and an air guiding element (10) mounted in the enclosure. The circuit board includes at least one heat generating component (41) thereon. The fan module has a fan (22) and an output opening (213) corresponding to the fan. The air guiding element comprises a resisting panel (11) and a guiding panel (12) comprises a free end that extends toward the output opening of the fan module. The at least one heat generating component and the output opening are on the same side of the resisting panel. The guiding panel defines a free end (127) and a connecting end (125) connecting the resisting panel. A plane defined by the ends of the guiding panel is aligned at an angle larger than 90 degrees relative to the resisting panel.

Abstract: A method for making a thin film transistor, the method comprising the steps of: providing a growing substrate; applying a catalyst layer on the growing substrate; heating the growing substrate with the catalyst layer in a furnace with a protective gas therein, supplying a carbon source gas and a carrier gas at a ratio ranging from 100:1 to 100:10, and growing a carbon nanotube layer on the growing substrate; forming a source electrode, a drain electrode, and a gate electrode; and covering the carbon nanotube layer with an insulating layer, wherein the source electrode and the drain electrode are electrically connected to the single-walled carbon nanotube layer, the gate electrode is opposite to and electrically insulated from the single-walled carbon nanotube layer.