Abstract: A liquid ingesting management system is provided. The liquid ingesting management system includes a fluid container, a database and a wireless transmit/receive unit. The wireless transmit/receive unit communicates with the fluid container and the database through a wireless technique to access the database and control the fluid container to perform a liquid ingesting management process.

Abstract: A liquid ingesting management system is provided. The liquid ingesting management system includes a fluid container, a database and a wireless transmit/receive unit. The wireless transmit/receive unit communicates with the fluid container and the database through a wireless technique to access the database and control the fluid container to perform a liquid ingesting management process.

Abstract: A liquid ingesting management system is provided. The liquid ingesting management system includes a fluid container, a database and a wireless transmit/receive unit. The wireless transmit/receive unit communicates with the fluid container and the database through a wireless technique to access the database and control the fluid container to perform a liquid ingesting management process.

Abstract: An intelligent electrical includes a metallic shielding case, an insulating main body, plural conducting terminals and at least one detecting element. The metallic shielding case includes a receiving space and at least one elastic sustaining element. The insulating main body includes a first body part and a second body part. The first body part is accommodated within the receiving space. The second body part is exposed outside the metallic shielding case. The detecting element is disposed on the second body part, arranged beside the elastic sustaining element of the metallic shielding case, and selectively contacted with or separated from the elastic sustaining element. When the elastic sustaining element is contacted with the detecting element, the electricity is permitted to be transmitted through the intelligent electrical connector. Whereas, when the elastic sustaining element is separated from the detecting element, the electricity fails to be transmitted through the intelligent electrical connector.

Abstract: A conductive winding structure, the fabricating method thereof, and the magnetic device having the same. The method for fabricating the conductive winding structure includes: (a) providing a mold with a plurality of extension portions and a plurality of protrusions, the plurality of extension portions are connected to each other as a continuous spiral structure, and the plurality of protrusions extend from the plurality of extension portions; (b) performing an electroforming procedure to form a conductive layer on partial surface of the mold; and (c) stripping the conductive layer from the mold, so as to obtain the conductive winding structure.

Abstract: An intelligent electrical includes a metallic shielding case, an insulating main body, plural conducting terminals and at least one detecting element. The metallic shielding case includes a receiving space and at least one elastic sustaining element. The insulating main body includes a first body part and a second body part. The first body part is accommodated within the receiving space. The second body part is exposed outside the metallic shielding case. The detecting element is disposed on the second body part, arranged beside the elastic sustaining element of the metallic shielding case, and selectively contacted with or separated from the elastic sustaining element. When the elastic sustaining element is contacted with the detecting element, the electricity is permitted to be transmitted through the intelligent electrical connector. Whereas, when the elastic sustaining element is separated from the detecting element, the electricity fails to be transmitted through the intelligent electrical connector.

Abstract: A power conversion circuit includes a driving circuit, an activating circuit, a converter and an auxiliary power source. The activating circuit receives a first power signal. The converter is used for converting the first power signal into a second power signal. The auxiliary power source is electrically connected to the activating circuit and the driving circuit. The auxiliary power source is driven by the driving circuit to issue either a first control signal to the activating circuit if the load is connected with the power conversion circuit or a second control signal to the activating circuit if the load is disconnected from the power conversion circuit. In response to the first control signal, the first power signal is converted into the second power signal and the second power signal is transmitted to the load. In response to the second control signal, the converter is disenabled.

Abstract: A connecting mechanism is provided for connecting a power adapter and an electronic device. The connecting mechanism includes a first connecting part and a second connecting part. The first connecting part is connected with the power adapter, and includes a first magnetic core, a first winding and a first magnetic element. The second connecting part is connected with the electronic device, and includes a second magnetic core, a second winding and a second magnetic element. The first magnetic element and the second magnetic element are aligned with and magnetically attracted by each other, so that the first connecting part is fixed onto the second connecting part and electromagnetic coupling between the first winding and the second winding is produced.

Abstract: An assembly structure includes a transformer, a system circuit board and an auxiliary circuit board. The transformer includes a primary winding coil, a secondary winding assembly and a magnetic core assembly. The magnetic core assembly is partially embedded within the primary winding coil and the secondary winding assembly. The secondary winding assembly has multiple output ends. The system circuit board is connected to the primary winding coil. The auxiliary circuit board is connected to the system circuit board and has multiple connecting parts. The output ends of the secondary winding assembly of the transformer are connected with corresponding connecting parts of the auxiliary circuit board.

Abstract: A power supply cord set includes a power connector and a power cord. The power connector includes an insulating body, a first conducting element and a second conducting element. The second conducting element includes a first conducting part having a first connecting segment and a second connecting segment. The power cord includes a first multi-core wire and a second multi-core wire, which are covered by the external insulating cover layer. The internal insulating cover layer is partially extended out of a distal aperture of the external insulating cover layer. The bare wire portion of the first multi-core wire is fixed on the first conducting element of the power connector. The bare wire portion of the second multi-core wire is fixed on the first connecting segment of the second conducting element. A terminal part of the internal insulating cover layer is fixed by the second connecting segment.

Abstract: A power supply cord set includes a power connector and a power cord. The power connector includes an insulating body, a first conducting element and a second conducting element. The second conducting element includes a first conducting part having a first connecting segment and a second connecting segment. The power cord includes a first multi-core wire and a second multi-core wire, which are covered by the external insulating cover layer. The internal insulating cover layer is partially extended out of a distal aperture of the external insulating cover layer. The bare wire portion of the first multi-core wire is fixed on the first conducting element of the power connector. The bare wire portion of the second multi-core wire is fixed on the first connecting segment of the second conducting element. A terminal part of the internal insulating cover layer is fixed by the second connecting segment.

Abstract: An assembly structure includes a transformer, a system circuit board and an auxiliary circuit board. The transformer includes a primary winding coil, a secondary winding assembly and a magnetic core assembly. The magnetic core assembly is partially embedded within the primary winding coil and the secondary winding assembly. The secondary winding assembly has multiple output ends. The system circuit board is connected to the primary winding coil. The auxiliary circuit board is connected to the system circuit board and has multiple connecting parts. The output ends of the secondary winding assembly of the transformer are connected with corresponding connecting parts of the auxiliary circuit board.

Abstract: A conductive winding structure, the fabricating method thereof, and the magnetic device having the same are disclosed. The method for fabricating the conductive winding structure comprises steps of: (a) providing a mold; (b) performing an electroforming procedure to form a conductive layer on partial surface of the mold; and (c) stripping the conductive layer from the mold, so as to obtain the conductive winding structure.

Abstract: A power conversion circuit includes a driving circuit, an activating circuit, a converter and an auxiliary power source. The activating circuit receives a first power signal. The converter is used for converting the first power signal into a second power signal. The auxiliary power source is electrically connected to the activating circuit and the driving circuit. The auxiliary power source is driven by the driving circuit to issue either a first control signal to the activating circuit if the load is connected with the power conversion circuit or a second control signal to the activating circuit if the load is disconnected from the power conversion circuit. In response to the first control signal, the first power signal is converted into the second power signal and the second power signal is transmitted to the load. In response to the second control signal, the converter is disenabled.

Abstract: The present invention relates to an electronic device having a passive heat-dissipating mechanism. The electronic device includes a circuit board and a radiation enhancement layer. The circuit board has at least an electronic component thereon. The radiation enhancement layer is attached onto at least a portion of a surface of the electronic component for facilitating radiating the heat from the electronic component to the ambient air via natural convection. The radiation enhancement layer is made of a ceramic material.

Abstract: The present invention relates to a power supply apparatus having a passive heat-dissipating mechanism. The power supply apparatus includes an insulating housing, a printed circuit board and at least an electronic component. The insulating housing has a closed receptacle therein and includes a first edge, a second edge and a third edge. The first edge is greater than the second edge and the second edge is greater than or equal to the third edge. An aspect ratio of the first edge to the second edge is greater than 2.5. The electronic component is mounted on the printed circuit board.

Abstract: An electronic connector includes a housing and a plurality of electricity-conducting elements. The housing has a channel therein. The electricity-conducting elements are separated from each other. Each electricity-conducting element includes a first conducting part and a second conducting part. The first conducting part is partially received within the housing and partially exposed to the channel. The second conducting part is extended from the housing. One of the electricity-conducting elements is selected to transmit an output voltage through the first conducting part and the second conducting part of the selected electricity-conducting element.

Abstract: An electronic device with a heat-dissipation structure is disclosed. The electronic device comprises a housing, a printed circuit board assembly, and a heat sink. The printed circuit board assembly is disposed in an interior of the housing, and the printed circuit board assembly forms a high-temperatured heat flow area and a low-temperatured heat flow area in the electronic device. The heat sink is disposed between the printed circuit board assembly and the housing and in the low-temperatured heat flow area for balancing heat flow and homogenizing temperature of the electronic device to enhance heat-dissipation efficiency.

Abstract: A power supply apparatus includes an insulating housing, a printed circuit board and at least an electronic component. The insulating housing has a substantially closed receptacle and made of a material having a thermal conductivity in a range of from 2.0 to 10.0 W/mK. The printed circuit board is accommodated within the receptacle of the insulating housing. The electronic component is mounted on the printed circuit board.

Abstract: A heat-dissipating device for radiating heat to the ambient air via natural convection includes a thermally conductive plate and a radiation-enhancing layer. The thermally conductive plate is mounted on a circuit board. The radiation-enhancing layer is attached onto a surface of the thermally conductive plate and having a higher emissivity than the thermally conductive plate. By means of such a structure of the heat-dissipating device, the heat generated from an electronic component on the circuit board is successively conducted to the thermally conductive plate, transferred to the radiation-enhancing layer and radiated from the radiation-enhancing layer to the ambient air via natural convection.