| TOSHIBA INTERNATIONAL CORPORATION Patent applications |
| Patent application number | Title | Published |
|---|
| 20120033472 | Multi-Phase Drive System - A drive system for driving a multi-phase motor (such as a three-phase AC motor) or other load. Where a transformer is used, the transformer may have a disconnected wye configuration on the secondary side. The system may also utilize the average or other combination of DC bus voltages of inverters for each load phase, to provide feedback control. | 02-09-2012 |
| 20110264292 | ADJUSTABLE UPS PROTECTION - An uninterruptable power supply (UPS) designed to switch power inputs between an alternating current mode and a battery mode by adjusting the amplitude and/or frequency windows of the input voltage so that the uninterruptible power supply accepts the unstable voltage and/or frequency. This prevents the uninterruptible power supply to switch back to the battery mode during a transfer time between the battery mode and the AC mode. The uninterruptable power supply includes a control circuit. The control circuit modifies the monitored value and/or actual amplitude and/or the frequency window when unstable amplitude and/or an unstable frequency are detected at the input terminal of the input voltage. | 10-27-2011 |
| 20110215646 | UPS AT THE RECOVERY MODE FROM THE POWER FAILURE - An uninterruptable power supply (UPS) designed to switch power inputs between an alternating current mode and a battery mode having a sensor to monitor a load current, and a control processing unit (CPU) to boost a bus voltage of the uninterruptable power supply by increasing a calculated reference voltage to a target reference voltage by a slope. The calculated reference voltage is calculated by the CPU based on a voltage drop value in main capacitors that occurs during a transfer time between the battery mode and the AC mode. The target reference voltage is the voltage across an equivalent circuit of the main capacitors before the voltage drop. The slope is based on a ratio of a voltage drop value across an equivalent circuit of main capacitors and a charging up time to reach the target reference voltage. | 09-08-2011 |
| 20110181159 | PROTECTIVE CABINET WITH ANGLED DEFLECTION BRACKET FOR UNINTERRUPTIBLE POWER SUPPLIES AND THE LIKE - A protective cabinet having an angled deflection bracket, the angled deflection bracket can include a first surface for catching falling debris, wherein said first surface is attached to an uninterruptible power supply, wherein said first surface is positioned at such an angle so as to make the debris impacting it, slide downward along its surface and reach a second surface configured to stop said sliding debris, wherein said second surface is attached to said first surface by a first corner. | 07-28-2011 |
| 20110109161 | UNINTERRUPTIBLE POWER SUPPLY - An uninterruptible power supply with an input terminal and an output terminal, a main switch connected to the input terminal, an input filter circuit connected to the main switch, a rectifier circuit connected to the input filter circuit, a main capacitor connected to the rectifier circuit, a switching device connected to the capacitor and the output terminal, a voltage boost circuit connected to the capacitor and a battery input terminal, a slope control circuit connected to the voltage boost circuit, a slope selection circuit connected to the slope control circuit, and a control board connected to the slope selection circuit, where the control board has a central processing unit and memory. | 05-12-2011 |
| 20100271045 | Open Fuse Detection by Neutral Point Shift - Systems and methods are shown for detecting a blown fuse in a three-phase line by comparing neutral points in the line before and after the fuses. Diode rectifier circuits may be used to compare the neutral points and generate a DC output voltage when neutral points are off from one another, and photocoupler circuits may provide electrical isolation when signaling a neutral point shift. The neutral points compared need not be on immediate sides of the fuses, so intermediate components may exist, and in some embodiments one of the compared points may be within a load connected to the three-phase line. | 10-28-2010 |
| 20100254171 | Medium Voltage Inverter System - An inverter system for driving electrical loads such as multi-phase induction motors is disclosed utilizing five single-phase inverter cells configured in a wye configuration. Inverter cells such as neutral-point-clamp inverter cells are configured to generate a voltage waveform between two output terminals and further configured with a terminal providing a neutral voltage reference point with respect to each of the two output terminals. The inverter cells may be configured with the neutral voltage reference points connected together and with one output terminal from each inverter cells connected together to provide three outputs of the inverter system at different voltage phases and with the common neutral reference point as the wye connection of the three outputs. The other three single phase inverter cells may be added to each of the three outputs to boost the output voltage of the inverter system and decrease the maximum voltage requirements on each inverter cell. | 10-07-2010 |
| 20100080021 | UNINTERRUPTIBLE POWER SUPPLY WITH TOTAL ISOLATION - An uninterruptible power supply includes an isolation transformer having dual primary windings. The secondary winding generates an output voltage based on the magnetic field generated in one of the dual primary windings. A first primary winding is coupled to an inverter circuit that receives an alternating current input voltage and applies a clean and filter alternating current to the first primary winding. A second primary winding is coupled to a bypass circuit that applies a bypass voltage when the inverter circuit is in a failure state. The power supply also includes a compensation circuit to maintain the output voltage at a desired level. | 04-01-2010 |
| 20090251935 | Multi-Pulse Rectifier for AC Drive Systems having Separate DC Bus Per Output Phase and Multiple Isolation Transformers - An 18n-pulse rectifier for AC drive systems having a separate DC bus for each output phase is provided, where n=any positive integer. The rectifier uses three separate phase rectifiers, one for each output phase of a transformer, each comprised of 2n six-pulse diode bridges connected in series or parallel. Each phase rectifier may be supplied with n unique sets of phase inputs from a transformer secondary winding. In some configurations, the n sets of inputs provided to each rectifier are separated by 60/n degrees of phase (when n is greater than 1), while the corresponding inputs to neighboring rectifiers are separated by 20/n degrees of phase. In a 36-pulse example, the phase offsets for the inputs provided to the rectifiers may be −25° and +5° from the transformer primary winding (for the first rectifier), −15° and +15° from the primary winding (for the second rectifier) and −5° and +25° from the primary winding (for the third rectifier). Each set of inputs may include three lines of in-phase current, and may be coupled to one of the six-pulse diode bridges. In some configurations, two identically-wound transformers may be used to supply output voltages to the rectifiers. The transformers may each supply the same phase offsets to each rectifier, in accordance with the methodology above, which may support higher-capacity applications. | 10-08-2009 |
| 20090251009 | Drive Isolation Transformer Controller and Method - A transformer controller for a drive isolation transformer is provided. The transformer may include multiple sets of primary windings as an input, and the transformer controller may include multiple branches coupled between a power source and the transformer. Each branch may be coupled to its own primary winding on the transformer, and may include one or more components, such as an isolation switch, a fuse, contactor, or circuit breaker. One or more of the branches may include a pre-charge reactor to limit inrush or capacitor charging current occurring during startup, and may include a pre-charge contactor to remove the pre-charge reactor from the circuit when the startup process has reached a certain level (e.g., the charging or inrush current has dissipated, or a DC bus reaches a charged state). | 10-08-2009 |
| 20090150818 | UNINTERRUPTIBLE POWER SYSTEM (UPS) WITH IMPROVED MANUAL USER INTERFACE HAVING A TOUCH SCREEN WITH MAIN TABS SEPARATING PAGES, SUB-MENUS IDENTIFYING SUB-PAGES RELATED TO CERTAIN MAIN TABS, AND LINKS TO PAGES OR SUB-PAGES - An Uninterruptible Power System configured to operate as a buffer between a supplied power and an electrical load such that if line voltage is interrupted power to the load is maintained for a period of time, said uninterruptible power system being characterized in that it has a user interface comprising: a touch screen having a display for presenting a graphical user interface and configured for manual user activation upon touching of said screen upon portions of the displayed graphical user interface; a control module having programming configured to display a graphical user interface on said touch screen, said graphical user interface including: a plurality of manually selectable tabs configured to present pages related to separate aspects of said uninterruptible power system; a menu configured to present sub-pages pertaining to respective ones of said tabs; wherein said tabs and said menu are located proximate a side of said touch screen; and at least one diagram including a plurality of regions having links to sub-pages pertaining to respective ones of said tabs. | 06-11-2009 |
| 20080205101 | Multi-Pulse Rectifier for AC Drive Systems Having Separate DC Bus Per Output Phase - An 18n-pulse rectifier for AC drive systems having a separate DC bus for each output phase is described, where n=any positive integer. The rectifier uses three separate phase rectifiers, one for each output phase of a transformer, each comprised of n six-pulse diode bridges connected in series or parallel. Each phase rectifier may be supplied with n unique sets of phase inputs from a transformer secondary winding. In some configurations, the n sets of inputs provided to each rectifier are separated by 60/n degrees of phase (when n is greater than 1), while the corresponding inputs to neighboring rectifiers are separated by 20/n degrees of phase. In a 36-pulse example, the phase offsets for the inputs provided to the rectifiers may be −25° and +5° from the transformer primary winding (for the first rectifier), −15° and +15° from the primary winding (for the second rectifier) and −5° and +25° from the primary winding (for the third rectifier). Each set of inputs may include three lines of in-phase current, and may be coupled to one of the six-pulse diode bridges. | 08-28-2008 |
