| Patent application number | Description | Published |
|---|
| 20100133905 | MULTI-OUTPUT POWER CONVERSION CIRCUIT - A multi-output power conversion circuit is provided for converting an input voltage into a standby voltage and a first output voltage. The multi-output power conversion circuit includes a transformer, a power switching circuit, a first rectifier-filter circuit, a second rectifier-filter circuit, a first switching circuit, a voltage-adjusting circuit, a feedback circuit and a power control circuit. The feedback circuit is connected to the first rectifier-filter circuit, the second rectifier-filter circuit and the system circuit. The feedback circuit generates a feedback voltage according to a power-status signal issued by the system circuit. The power control circuit is interconnected between the power switching circuit and the feedback circuit for controlling on/off statuses of the power switching circuit according to the feedback voltage. The feedback circuit generates the feedback voltage according to the power-status signal and selectively according to the first DC voltage or the second DC voltage. | 06-03-2010 |
| 20100270945 | CURRENT-SHARING TRANSFORMER AND POWER SUPPLY CIRCUIT HAVING SUCH CURRENT-SHARING TRANSFORMER - A current-sharing transformer includes a magnetic core assembly, a primary winding coil and multiple secondary winding coils. The magnetic core assembly includes a main magnetic post and multiple minor magnetic posts. The primary winding coil is wound around the main magnetic post. The secondary winding coils wound around respective minor magnetic posts. The secondary winding coils are connected to respective DC loads through respective rectifier circuits. The magnetic paths between respective minor magnetic posts and the main magnetic post are equal, so that the magnitudes of currents passing through the DC loads are balanced by the current-sharing transformer. | 10-28-2010 |
| 20100270947 | CURRENT-SHARING SUPPLY CIRCUIT FOR DRIVING MULTIPLE SETS OF DC LOADS - A current-sharing supply circuit includes a current providing circuit, a current-sharing circuit, a first output rectifier circuit and a second output rectifier circuit. The current providing circuit receives an input voltage and generating a first current or a first voltage, thereby providing electrical energy to a first set of DC loads and a second set of DC loads. The first output rectifier circuit is interconnected between the first set of DC loads and a first output terminal of the current-sharing circuit, thereby generating a first output current to the first set of DC loads. The second output rectifier circuit is interconnected between the second set of DC loads and a second output terminal of the current-sharing circuit, thereby generating a second output current to the second set of DC loads. The first output current and the second output current are balanced by the current-sharing circuit. | 10-28-2010 |
| 20110006604 | CURRENT-SHARING SUPPLY CIRCUIT FOR DRIVING MULTIPLE SETS OF DC LOADS - A current-sharing supply circuit includes a current providing circuit, a first output rectifier circuit, a second output rectifier circuit, a first current-sharing transformer, a second current-sharing transformer, a first current-sharing circuit and a second current-sharing circuit. By adjusting the equivalent impedance values of the first current-sharing circuit, the second current-sharing circuit, the primary winding coil of the first current-sharing transformer and the primary winding coil of the second current-sharing transformer, the first output current and the second output current are substantially identical. | 01-13-2011 |
| 20110006605 | CURRENT-SHARING SUPPLY CIRCUIT FOR DRIVING MULTIPLE SETS OF DC LOADS - A current-sharing supply circuit is provided for driving a first set of main DC loads, a first set of minor DC loads, a second set of main DC loads and a second set of minor DC loads. The current-sharing supply circuit includes a current providing circuit, a first output rectifier circuit, a second output rectifier circuit, a first main current-sharing circuit and a second main current-sharing circuit. By adjusting an equivalent impedance value of the first main current-sharing circuit to be impedance matched with that of the first set of main DC loads and that of the first set of minor DC loads, respectively, and adjusting an equivalent impedance value of the second main current-sharing circuit to be impedance matched with that of the second set of main DC loads and that of the second set of minor DC loads, respectively, a first main output current, a first minor output current, a second main output current and a second minor output current passing through these DC loads are substantially identical. | 01-13-2011 |
| 20110012881 | POWER SUPPLY CIRCUIT AND CONTROL METHOD THEREOF - A power supply circuit for receiving an input voltage to drive a plurality of loads is disclosed. The power supply circuit comprises a plurality of switch circuits, a plurality of power conversion circuits and a phase delay circuit. The plurality of switch circuits are connected with the plurality of loads, respectively. The plurality of power conversion circuits are connected with the plurality of loads and the plurality of switch circuits, respectively, for converting the input voltage into a plurality of driving voltages and transmitting the plurality of driving voltages to the plurality of loads, respectively, when the plurality of switch circuits are conducted. The phase delay circuit is connected with the plurality of switch circuits and a system circuit for generating a plurality of delay signals in response to a switch signal from the system circuit and transmitting the plurality of delay signals to control terminals of the plurality of switch circuits, respectively, so as to make the plurality of switch circuits be conducted or shut off. The plurality of delay signals are converted into an enabling status from a disabling status at different time points so that the plurality of switch circuits are conducted at different time points. | 01-20-2011 |
