| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 323247000 | Using a transformer or inductor as the final control device | 58 |
| 20080309299 | Inductor assembly having a core with magnetically isolated forms - An embodiment of an inductor assembly includes a core, a first conductor, and a second conductor. The core includes first and second members, a first group of one or more forms extending between the members, a second group of one or more forms extending between the members, and an isolating region that magnetically isolates the first group of forms from the second group of forms. The first conductor is wound about a first one of the forms in the first group, and the second conductor is wound about a second one of the forms in the second group. Such an inductor assembly may allow both coupled and uncoupled inductors to be disposed on a common core, thus potentially reducing the cost and size of the inductors as compared to the coupled inductors being disposed on one core and the uncoupled inductors being disposed on another core. | 12-18-2008 |
| 20090051334 | Droop circuits and multi-phase DC-DC converters - A droop circuit of a DC-DC converter is provided, wherein the DC-DC converter includes an output inductor coupled between an output of the DC-DC converter and a phase node for providing an output voltage. A current sense device is coupled between the phase node and the output of the DC-DC converter, includes an inductor coupled to the phase node and senses a current from the phase node. A first resistor is coupled to the current sense device. An amplifier circuit includes an amplifier having an inverting input, a non-inverting input coupled to the first resistor and an output directly connected to the inverting input, and a second resistor coupled between the inverting input and the output of the DC-DC converter. The amplifier circuit provides a droop current according to the second resistor and a voltage difference between the non-inverting input and the output of the DC-DC converter, and the voltage difference is related to the current. | 02-26-2009 |
| 20090066300 | Power Converter Employing a Micromagnetic Device - A power converter including a power train, a controller and a driver. In one embodiment, the power train includes a switch that conducts for a duty cycle and provides a regulated output characteristic for the power converter, and a micromagnetic device. The micromagnetic device includes a first conductive winding layer selectively formed above a first seed layer, and first and second magnetic core layers formed thereabove. The micromagnetic device also includes a second seed layer formed above the second magnetic core layer, and a second conductive winding layer formed above the second seed layer and in vias to the first conductive winding layer. The first and second conductive winding layers form a winding for the micromagnetic device. The controller provides a signal to control the duty cycle of the switch, and the driver provides a drive signal to the switch as a function of the signal from the controller. | 03-12-2009 |
| 20090072798 | APPARATUS AND METHOD FOR APPLYING HIGH VOLTAGE WITH HIGH FREQUENCY - An apparatus and a method for applying high voltage with high frequency. The apparatus includes a power generator for generating electric power with predetermined frequency, a voltage transformer receiving the electric power generated by the power generator, amplifying voltage of the electric power received, and applying the amplified voltage to a load, and an impedance matcher connected between the power generator and the voltage transformer to match impedances of the power generator and the voltage transformer to thereby transmit the electric power to the voltage transformer. High voltage with high frequency is obtained by transmitting the electric power generated from the power generator to the load without reflecting loss while conducting an impedance matching, and amplifying the voltage applied to the load using the coupled inductor and LC resonance. | 03-19-2009 |
| 20090128103 | AC HIGH VOLTAGE POWER SUPPLY DEVICE, CHARGING DEVICE, DEVELOPING DEVICE, AND IMAGE FORMING APPARATUS - An AC high voltage power supply device includes a comparison circuit configured to compare a first signal of a sinusoidal waveform and a second signal of a triangular waveform; a switching amplifier circuit configured to perform a switching operation based on a comparison result signal output from the comparison circuit to perform signal amplification; a conversion circuit configured to convert a waveform of a switch signal output from the switching amplifier circuit into a sinusoidal waveform; a transformer configured to boost a voltage of a converted signal output from the conversion circuit; and a control circuit configured to perform feedback control on the first signal input to the comparison circuit based on a monitoring signal including an input signal or an output signal of the transformer, so that a peak level of the output signal of the transformer becomes a desired peak level. | 05-21-2009 |
| 20090140704 | METHOD FOR THE OPERATION OF A WIND ENERGY PLANT WITH VOLTAGE-DEPENDENT CONTROL OF A REACTIVE ELECTRIC VARIABLE WHICH IS TO BE PROVIDED - A method for the operation of a wind energy plant, with control of a reactive electric variable which is to be provided, wherein a desired value for the reactive electric variable is determined as follows: a first upper and/or a first lower limit value of the grid voltage is defined for the grid voltage, when the real value of the grid voltage exceeds the first upper limit value and/or the real value of the grid voltage falls below the first lower limit value, the desired value of the reactive electric variable is increased or diminished such that the deviation of the real value of the grid voltage from its desired value is counter-acted, wherein the desired value of the reactive electric variable is continuously increased or diminished further over the time, as long as the real value of the grid voltage exceeds the first upper limit value or falls below the first lower limit value. | 06-04-2009 |
| 20100019743 | DC-DC CONVERTER - The present invention provides a DC-DC converter including a first series circuit connected to both ends of a first switch and formed of a winding of a first transformer, a first reactor, a first diode, and a smoothing capacitor, a second diode connected to a connection point of a primary winding of the first transformer, the winding of the first transformer and the first switch, and to one end of the smoothing capacitor, a second series circuit connected to both ends of a second switch and formed of a winding of a second transformer, a second reactor, a third diode, and the smoothing capacitor, a fourth diode connected to a connection point of a primary winding of the second transformer, the winding of the second transformer and the second switch, and to the one end of the smoothing capacitor, a third reactor connected to both ends of a series circuit of a secondary winding of the first transformer and a secondary winding of the second transformer, and a control circuit which alternately turns on the first switch and the second switch every ½ cycle, turns off the first switch during an on-period of the second switch, and turns off the second switch during an on-period of the first switch. | 01-28-2010 |
| 20100033143 | Switching power converter and controller - A switching power converter includes an input for receiving an input voltage, an output for providing an output voltage, a controller, and a power circuit coupled between the input and the output and including at least one switch. The controller is configured to determine a duty cycle for the switch to regulate the output voltage and control the switch with a PWM drive signal having an on-time and an off-time. The PWM drive signal has a constant frequency and a duty cycle equal to the determined duty cycle when the determined duty cycle is greater than or equal to a minimum duty cycle. The PWM drive signal has a variable frequency and a duty cycle equal to the minimum duty cycle when the determined duty cycle is less than the minimum duty cycle. | 02-11-2010 |
| 20100052630 | HIGH FREQUENCY POWER CONVERTER BASED ON TRANSFORMERS - A transformer-based power conversion system includes a primary coil is provided in a current path that includes a single energy switch. An oscillator is coupled to a control input of the energy switch. The design conserves switch-based losses as compared to prior designs because a single switch is provided in a current path occupied by the primary coil. The design also provides improved conversion efficiency because parasitic capacitances associated with the energy switch cooperate with charge transfers generated by the oscillator. | 03-04-2010 |
| 20100164443 | METHOD FOR CONTROLLING A SWITCHING REGULATOR AND RELATED SWITCHING REGULATOR - An embodiment of a power-supply controller comprises a switching-control circuit, an error amplifier, and a signal generator. The switching-control circuit is operable to control a switch coupled to a primary winding of a transformer, and the error amplifier has a first input node operable to receive a feedback signal, a second input node operable to receive a comparison signal, and an output node operable to provide a control signal to the switching-control circuit. The signal generator is operable to generate either the feedback signal or the comparison signal in response to a compensation signal that is isolated from a secondary winding of the transformer and that is proportional to a load current through a conductor disposed between the secondary winding and a load. | 07-01-2010 |
| 20100188061 | METHOD AND APPARATUS FOR SWITCHING A SYNCHRONOUS DC/DC CONVERTER BETWEEN A PWM MODE OF OPERATION AND A LIGHT-LOAD MODE OF OPERATION - A synchronous buck converter operates in a PWM mode of operation and switches to light-load mode of operation under a light-load condition. When operating in the light-load mode, the synchronous buck converter transitions between a burst mode and an idle mode of operation. In the burst mode of operation, the converter operates with a fixed but increased duty ratio, with respect to the PWM mode of operation, that installs additional energy in an output capacitor. In the idle mode of operation, the high-side and low-side transistors are each turned off. To maximize energy savings and to quickly transition back to the PWM mode of operation if the load increases, a limit as to the number of allowed switching cycles when bursting is imposed and a minimum ratio of the number of clock cycles when idling to the number of switching cycles when bursting is set. Additionally, a comparator is provided to detect a sudden step-increase in the load to quickly switch the converter back to the PWM mode of operation. | 07-29-2010 |
| 20100289463 | PRIMARY-SIDE FEEDBACK CONTROL DEVICE AND RELATED METHOD FOR A POWER CONVERTER - A primary-side feedback control device for a power converter includes a control unit, a comparator and a sample-and-hold unit. The control unit is utilized for generating a pulse signal according to a feedback signal for controlling on and off states of a switching transistor of the power converter. The comparator is coupled to an auxiliary winding of a primary side of the power converter, and is utilized for generating at least one control signal according to a voltage on the auxiliary winding. The sample-and-hold unit is coupled to the auxiliary winding, the comparator and the control unit, and is utilized for generating the feedback signal according to the voltage on the auxiliary winding and the at least one control signal. | 11-18-2010 |
| 20110193536 | 10GBASE-T TRAINING ALGORITHMS - A method of identifying and correcting each of the changes that may occur with wire pairs between the transmitter and receiver in Ethernet 10GBase-T cabling is provided. The method includes four wire pairs A, B, C and D, a polarity swapping and scrambler state machine that determine if the chosen pair matches the requirements for pair A. A slave Tap state machine generates a rule for correct B, C and D patterns based on a pair chosen as pair A. The cables B, C and D are iteratively swapped to rearrange the pair mapping into the polarity swap state machine, and a deskew state machine identifies the latency difference between the different pairs. If the rules are not satisfied, a new pair A is designated at the swapping state machine and the process is repeated until the rules are satisfied. | 08-11-2011 |
| 20120062188 | POWER SUPPLY DEVICE AND IMAGE FORMING APPARATUS INCLUDING THE POWER SUPPLY DEVICE - A power supply device includes an AC generation part having a sinusoidal wave generation part generating a first sinusoidal wave signal, an integrator integrating a difference between the first sinusoidal wave signal and a feedback signal, a triangular wave generation part generating a triangular wave signal, a comparator comparing an output of the integrator and the triangular wave signal and outputting a PWM signal, a switching drive part amplifying the PWM signal and outputs an amplified PWM signal, a filter converting the amplified PWM signal into a second sinusoidal wave signal, a transformer increasing a voltage of the second sinusoidal wave signal and outputting an AC voltage, and a voltage divider dividing the AC voltage and generating the feedback signal, and a DC generation part generating a DC voltage. The power supply device superimposes the AC voltage and the DC voltage and outputs a superimposed voltage. | 03-15-2012 |
| 20130113444 | MULTIPHASE TRANSFORMER FOR A MULTIPHASE DC-DC CONVERTER - A multiphase DC-DC converter is provided that includes a multiphase transformer, the multiphase transformer including a plurality of input voltage terminals and an transformer output voltage terminal, each input voltage terminal associated with a corresponding phase. Each phase is assigned to an input voltage terminal of the plurality of input voltage terminals to minimize a ripple current at the input voltage terminals of the multiphase transformer. | 05-09-2013 |
| 20130154586 | SYSTEM AND METHOD FOR CONTROLLING OUTPUT RIPPLE OF DC-DC CONVERTERS WITH LEADING EDGE MODULATION CONTROL USING CURRENT INJECTION - In a preferred embodiment, a voltage converter comprises a voltage converter circuit, an output adjuster and a controller. The controller provides a control signal at a duty ratio determined dynamically by a set of input signals. The dynamic output adjuster determines the set of input signals by adjusting the ac component of an output voltage based on a gain Q. The dynamic output adjuster alleviates dependence on the value of R | 06-20-2013 |
| 20130249507 | APPARATUS AND METHOD FOR CONTROLLING PULSE FREQUENCY MODULATION IN SINGLE-INDUCTOR DUAL-OUTPUT POWER CIRCUIT - An apparatus configured to control a pulse frequency modulation in a single-inductor dual-output power circuit. The apparatus fixes a pulse width of one of a maximum on-time pulse signal (which is used to define a maximum on-time during which a current flowing through the inductor is generated) and a minimum off-time pulse signal (which is used to define a minimum off-time during which either the boost voltage converter or the buck-boost voltage converter produces a positive voltage or a negative voltage). The apparatus adjusts a pulse width of the other pulse signal. | 09-26-2013 |
| 20140197808 | DC-DC CONVERTER - A DC-DC converter, adapted to control a converting circuit to convert an input voltage into an output voltage, is disclosed. The converting circuit comprises a switch module and an LC filter, the switch module is coupled to the input voltage, and the LC filter is coupled to the switch module and provides the output voltage. The DC-DC converter comprises a system control circuit, a driver circuit, and an output voltage adjusting circuit. The system control circuit generates a switch control signal according to a reference voltage and a state of the LC filter. The driver circuit controls the switch module according to the switch control signal for adjusting the output voltage in response to the reference voltage. The output voltage adjusting circuit determines whether adjusting the output voltage toward a predetermined adjusting voltage according to an adjusting reference voltage and a detecting voltage indicative of the output voltage. | 07-17-2014 |
| 20140312859 | PHASE BALANCING OF POWER TRANSMISSION SYSTEM - Phase balancing techniques for power transmission systems are disclosed. In one embodiment, a phase balancing protocol ( | 10-23-2014 |
| 323249000 | Controllably saturable | 4 |
| 20080238378 | Voltage regulator - In some embodiments, a voltage regulator assembly comprises a first voltage regulator circuit selectively coupled to a first input voltage and comprising a first inductor, a second regulator circuit selectively coupled to the first input voltage and comprising a second inductor to inductively couple the second regulator circuit to the first voltage regulator circuit, a bypass switch coupled to the second regulator circuit, and a controller coupled to the bypass switch comprising logic to activate the bypass switch when a load on the voltage regulator assembly falls below a threshold. Other embodiments may be described. | 10-02-2008 |
| 20130320940 | POWER FLOW CONTROL USING DISTRIBUTED SATURABLE REACTORS - A magnetic amplifier includes a saturable core having a plurality of legs. Control windings wound around separate legs are spaced apart from each other and connected in series in an anti-symmetric relation. The control windings are configured in such a way that a biasing magnetic flux arising from a control current flowing through one of the plurality of control windings is substantially equal to the biasing magnetic flux flowing into a second of the plurality of control windings. The flow of the control current through each of the plurality of control windings changes the reactance of the saturable core reactor by driving those portions of the saturable core that convey the biasing magnetic flux in the saturable core into saturation. The phasing of the control winding limits a voltage induced in the plurality of control windings caused by a magnetic flux passing around a portion of the saturable core. | 12-05-2013 |
| 323250000 | With specific core structure (e.g., gap, aperture, slot, permanent magnet) | 1 |
| 20150028827 | TRANSFORMER CORE FLUX CONTROL FOR POWER MANAGEMENT - An electromagnetic device may include a magnetic flux core and an opening through the magnetic flux core. A conductor winding may be received in the opening and extend through the magnetic flux core. An electrical current flowing through the conductor winding generates a magnetic field about the conductor winding and a magnetic flux flow about the opening in the magnetic flux core. The electromagnetic device may also include a core flux sensor arrangement to detect a magnetic flux level in the magnetic flux core. The electromagnetic device may additionally include a core flux control system configured to adjust the electrical current flowing through the conductor winding to control the magnetic flux level in the magnetic flux core. | 01-29-2015 |
| 323251000 | With plural power windings | 1 |
| 323253000 | On different cores | 1 |
| 20100327824 | POWER SUPPLY USING SHARED FLUX IN A MULTI-LOAD PARALLEL MAGNETIC CIRCUIT - A flux sharing magnetic circuit has a parallel arrangement of secondary flux loops with secondary windings to drive output loads. A shared pool of flux is provided by a primary winding. An AC driven primary delivers current to the secondary circuits to maintain a desired voltage or current to a load. One or more control windings control current in the parallel flux loops and thus control the power delivered to the loads. | 12-30-2010 |
| 323255000 | Having a variable length winding (e.g., tapped) as the final control device | 24 |
| 20090079402 | SWITCHING POWER SUPPLY - This switching power supply provides a stable output. In the switching power supply, at least pairs of secondary side coils are connected to each of the center tap rectifier circuits and the secondary side coils of each of the center tap rectifier circuits are disposed in the core portions (cores) of mutually different transformers. | 03-26-2009 |
| 20090134854 | APPARATUS AND METHODS FOR CONTROLLING OPERATION OF A SINGLE-PHASE VOLTAGE REGULATOR IN A THREE-PHASE POWER SYSTEM - Provided are methods for controlling operation of a voltage regulator of a single-phase of a three-phase power system to regulate a measured voltage. One of the methods includes recording a first elapsed time between detecting a first excursion of the measured voltage from an in-band area to an out-of-band area, and a first return of the measured voltage to the in-band area. The method also includes recording a second elapsed time period (dip period) between detecting the first return and a second excursion of the measured voltage from the in-band area to an out-of-band area. If the second elapsed time period is less than a predetermined dip time period, causing a tap position change of the voltage regulator upon expiration of a countdown period initiated upon detecting the first excursion, thereby adjusting the measured voltage to the in-band area while allowing a voltage drop of limited length. | 05-28-2009 |
| 20100045246 | Apparatus And Method For Reverse Power Regulation With Measured Source Side Voltage - An apparatus and method for measuring the source-side line voltage from a source potential transformer (PT) of a regulator during reverse power flow. A reverse power regulation algorithm (“Source Side PT”) is employed during reverse power operation of the tapchanger to energize a contact relay which switches the analog voltage input from the load side to the source side of the regulator. Voltage regulation then operates based on the measured source side voltage instead of the traditional calculation of the source side voltage based upon the load-side voltage and regulator type. | 02-25-2010 |
| 20110084672 | SYSTEMS AND METHODS FOR SYNCHRONIZED CONTROL OF ELECTRICAL POWER SYSTEM VOLTAGE PROFILES - Disclosed herein are various embodiments of systems and methods for controlling a voltage profile delivered to a load in an electric power system. According to various embodiments, an electric power system may include an electric power line, a variable tap transformer, and a capacitor bank. The variable tap transformer may include a plurality of tap positions. A tap change controller may be coupled with the variable tap transformer and may control the tap positions of the variable tap transformer. A capacitor bank controller may be coupled with the capacitor bank and may selectively couple the capacitor bank to the electric power line. The tap change controller and the capacitor bank controller may share system information related to the voltage profile along the electric power line and to change the voltage profile along the line using the variable tap transformer and the capacitor bank depending on the system information. | 04-14-2011 |
| 20110121796 | Voltage Regulation System - A tap-switching autotransformer for regulating the voltage supplied to a facility includes an electronics sub-assembly for controlling switching of the taps. The electronics sub-assembly and the windings are contained in a housing from which the electronics sub-assembly may be removed for repair or replacement. The electronics sub-assembly is adapted to enable an electronically actuated switch to short-circuit two of the taps. A mechanical switch enables a separate short-circuit to be maintained between the taps to enable the electronics sub-assembly to be safely removed from the housing. | 05-26-2011 |
| 20110273149 | AUTOMATIC VOLTAGE REGULATOR AND TOROIDAL TRANSFORMER - The present invention relates to an automatic voltage regulator and a toroidal transformer, comprising: a main winding; a primary field winding excited in the main winding; a first switch unit for selectively connecting one end of the primary field winding to either a reference potential or the output terminal; a plurality of secondary field windings excited in the main winding; a second switch unit for selectively switching so that the plurality of secondary field windings are selectively connected to the primary field winding serially; a third switch unit for selectively connecting an end of a serial connection generated by selectively connecting the primary field winding and the secondary field windings to either the reference potential or the input terminal; and a control unit which regulates the level of an output voltage output to the output terminal. | 11-10-2011 |
| 20130057235 | AC ELECTRICAL POWER REGULATORY SYSTEM - A system is provided for regulating AC electrical power delivered from a source to a load. The system has a voltage regulating device which, in use, is connected at an input side thereof to the source and at an output side thereof to the load. The voltage regulating device is controllable to vary the ratio of voltage amplitudes at the input side and the output side. | 03-07-2013 |
| 20130187622 | VOLTAGE EQUALIZATION DEVICE AND A MEDICAL IMAGING DEVICE HAVING A VOLTAGE EQUALIZATION DEVICE - A voltage equalization device for equalizing voltage fluctuations in a voltage supply is provided. The voltage supply has an electrical voltage that is as constant as possible. The voltage equalization device has at least one transformer unit which has a primary winding unit and a secondary winding unit and, on one of the two winding units, has at least three or more selection units for switching in or switching out turns of the winding unit. Two adjacent selection units are so arranged in each case as to be separated from one another by a distance having a number of turns. The number of turns between two first adjacent selection units is different from the number of turns between two further adjacent selection units. | 07-25-2013 |
| 20130229158 | Managed Multi-Phase Operation - Systems and methods for maximum deviation multi-phase operation provide techniques for controlling voltage regulators and tap changers in a multi-phase system to operate within a maximum deviation window. The maximum deviation window comprises a low boundary value and a high boundary value. In an example embodiment, systems and methods provide techniques for setting the low boundary value and the high boundary value. In another example embodiment, systems and methods provide techniques for optimized power factor correction in a multi-phase system | 09-05-2013 |
| 20130229159 | Multi-Phase Operation with Single Phase Control - A multi-phase control system having multi-phase operation with single phase control includes a main control module, a lineman module, and an add-on lineman module. The main control module and the lineman module control, automatically or manually, the first phase and first phase tap changer of a multi-phase system. The add-on lineman module and the main control module control, automatically or manually, additional phases of the multi-phase system. In certain example embodiments, the multi-phase control system detects when a line voltage of an additional phase is de-energized and allows the tap changer of the additional phase to be powered by a line voltage of the first phase. In certain example embodiments, the tap changer of a de-energized phase is powered by an external power supply. | 09-05-2013 |
| 323256000 | With motor driven tap switch | 3 |
| 20100001700 | SYSTEM FOR VOLTAGE REGULATION, CONTROL PROTECTION AND MONITORING OF STATE OF CHANGERS UNDER POWER TRANSFORMER LOAD, VOLTAGE REGULATORS, CAPACITOR BANKS AND SIMILAR - System for voltage regulation, control, protection and monitoring of state of changers under power transformer load, voltage regulators, capacitor banks and similar”, is preferably applied to power transformers ( | 01-07-2010 |
| 20160147237 | METHOD AND SYSTEM FOR VOLTAGE REGULATION, CONTROL, PROTECTION AND MONITORING OF STATE OF ON-LOAD TAP CHANGERS OF POWER TRANSFORMERS, VOLTAGE REGULATORS, AND CAPACITOR BANKS - A method for voltage regulation, control, protection and monitoring of state of on-load tap changers of power transformers, voltage regulators, and capacitor banks comprising: uses a voltage regulation system that has sets of voltage regulation parameters available for programming by a user. Each of these sets is adjustable in an independent manner for a given prevailing load condition. The parameters include a desired rated voltage at a load; a voltage variance percentage allowed over and below rated voltage; time delay adjustments for CDC ( | 05-26-2016 |
| 323257000 | Including an electronic tube or a three or more terminal semiconductive device in control circuit | 1 |
| 20120206115 | APPARATUS AND METHOD FOR GENERATING A METERING VOLTAGE OUTPUT FOR A VOLTAGE REGULATOR USING A MICROPROCESSOR - A voltage regulator ( | 08-16-2012 |
| 323258000 | With electronic tube or a three or more terminal semiconductive device as tap switch | 11 |
| 20090102438 | USEFUL IMPROVEMENTS IN THE ART OF 3-PHASE ELECTRONIC TAP CHANGER COMMUTATION DEVICE - The invention is for a 3-phase electronic tap changer commutation device to be utilized in electronic regulators, and more particularly to 3-phase alternating current (AC) electronic tap-changing voltage, current or phase correcting regulators. The present invention provides a specific transformer winding topology and commutation technique that improves performance and reduces cost compared to conventional methods. | 04-23-2009 |
| 20090140705 | Device for Regulating Electrical Voltage - The invention relates to a device for regulating the electrical voltage in power mains, comprising a regulating transformer. Optionally interconnecting only three winding taps and a separate reactor winding with a total of four switching elements, enables five different voltage levels to be set. | 06-04-2009 |
| 20090230933 | HYBRID ON-LOAD TAP CHANGER AND A METHOD OF OPERATING THE SAME - A hybrid on-load tap changer, for use in high voltage alternating current power transmission, including a selector and a diverter having two legs defining respective current paths. Each leg includes a pair of opposed first and second semiconductor switches. The hybrid on-load tap changer also includes a controller configured to switch on one of the first or second semiconductor switches of a given leg at a predetermined point within the alternating current cycle so as to commutate off a desired semiconductor switch in the other leg. | 09-17-2009 |
| 20100164444 | TRANSFORMING APPARATUS FOR AUTOMATICALLY ADJUSTING THREE-PHASE POWER SUPPLY VOLTAGE - A transforming apparatus automatically adjusting the voltage of three-phase power supply comprising three input terminals, three output terminals, a Y-connection three-phase transformer, a switch group, and a switch switching circuit. The three input terminals are respectively connected to three main lines of the three-phase power supply, and the three output terminals are connected to a load installation. The Y-connection three-phase transformer comprises a core, an R-phase winding circuit, an S-phase winding circuit, and a T-phase winding circuit. In the R-phase winding circuit, an R-phase main winding, an R-phase first auxiliary winding, an R-phase first switch, an R-phase second auxiliary winding, and an R-phase third auxiliary winding are serially connected in that order between the input terminal Rin and a neutral point O, the output terminal Rout being connected to the other end of the R-phase main winding. An R-phase second switch is connected in parallel with a series circuit of the R-phase first auxiliary winding and the R-phase first switch. An R-phase third switch is connected in parallel with a series circuit of the R-phase first auxiliary winding, the R-phase first switch, and the R-phase second auxiliary winding. An R-phase fourth switch is connected in parallel with a series circuit of the R-phase second auxiliary winding and the R-phase third auxiliary winding. The switch switching circuit controls the switches based on the voltage levels of the output terminals to switch between first to fourth modes in an alternative manner. | 07-01-2010 |
| 20110012572 | HEAT-EXCHANGE COOLING DEVICE AND POWER SUPPLY CIRCUIT DRIVER USED THEREFORE - A heat exchange cooler capable of eliminating continuous radiation of high-frequency noise waves and reducing the man hour for the installation work, and a power circuit driving device used for it are provided. A commercial power transformer ( | 01-20-2011 |
| 20110285364 | PHASE-FIRED CONTROL ARRANGEMENT AND METHOD - A method and arrangement for phase-fired control is provided, in which all controllable electric switching elements are linked by a common controller that has a first input for a first control signal. A set point value is pre-defined as a first input variable and assigned to a device for controlling the controllable electric switching elements. Current flowing through each switching element is measured and transmitted to the device for controlling the switching elements as a respective second input variable. The current value of the voltage in the load is measured and transmitted to the device for controlling the switching elements as a third input variable. The device for controlling the switching elements controls all switching elements in a targeted manner by use of the first, second and third input variables. A maximum of two switching elements are active at any one time. | 11-24-2011 |
| 20110316498 | POWER REGULATOR AND REMOTE POWER CONTROL DEVICE - A power regulator | 12-29-2011 |
| 20120025789 | ON-LOAD TAP CHANGER COMPRISING SEMICONDUCTOR SWITCHING ELEMENTS - The invention relates to an on-load tap changer comprising semiconductor switching elements for uninterrupted switching between winding taps of a tapped transformer. According to the invention, contact bars are provided which extend in the direction of the path of the fixed tap contacts and can be contacted using contact bridges that can be jointly moved by a contact slide in such a way that direct electrical connections to the charge diverter and electrical connections to the inputs and the output of the semiconductor switching elements can be established. | 02-02-2012 |
| 20120032654 | ON-LOAD TAP CHANGER COMPRISING SEMICONDUCTOR SWITCHING ELEMENTS - The invention relates to an on-load tap changer comprising semiconductor switching elements for uninterrupted switching between fixed tap changer contacts which are electrically connected to winding taps of a tapped transformer. Each of the fixed tap changer contacts can be connected to a charge diverter either directly or, during switching, via the semiconductor switching elements that are connected therebetween. According to the invention, the charge diverter has fixed, divided diverting contact pieces in order for the semiconductor switching elements to be electrically isolated from the transformer winding during stationary operation. | 02-09-2012 |
| 20120139510 | TAP CHANGER WITH VACUUM SWITCH TUBES - The invention relates to a stepping switch comprising vacuum switching tubes. The general inventive concept consists in providing one or more cam disks which have profiled circumferential contours both on the upper or lower face as well as on the lateral face, said contours being in the shape of cams for example, so that the vacuum switching tubes can be actuated by both the profiled circumferential contour of the lateral face as well as by the contour of the upper or lower face. | 06-07-2012 |
| 20120313594 | STEP SWITCH - The invention relates to a step switch comprising semiconductor switches for uninterrupted switching between tap windings of a step transformer. The switch is a hybrid switch that has fixed mechanical contact fingers and counter-contacts situated on a movable contact carrier. Semiconductor switch units are provided for the actual load switching, said units being actuated in a predetermined switching sequence by the contacts on the contact carrier. | 12-13-2012 |
| 323259000 | Having a winding in series with the source and load (e.g., buck-boost) | 11 |
| 20090045786 | MODE TRANSITIONING IN A DC/DC CONVERTER USING A CONSTANT DUTY CYCLE DIFFERENCE - According to an exemplary embodiment, a method includes the step ( | 02-19-2009 |
| 20090174375 | Sepic fed buck converter - A Single Ended Primary Inductance Converter (SEPIC) fed BUCK converter includes: a first switch configured to open or close according to a first signal; a SEPIC portion coupled to the first switch and coupled to an energy source, the SEPIC portion comprising a first set of one or more passive components; a BUCK converter portion coupled to the first switch, the BUCK converter portion comprising a second set of one or more passive components. While the first switch is closed, the SEPIC portion is configured to store energy from an energy source in at least some of the first set of passive components and deliver energy to the BUCK portion, and the BUCK converter portion is configured to deliver energy to a load and to store energy in at least some of the second set of passive components. While the first switch is open, the SEPIC portion is configured to deliver at least some of its stored energy to the load, and the BUCK converter portion is configured to deliver at least some of its stored energy to the load. | 07-09-2009 |
| 20090267576 | POWER CONVERTER WITH SNUBBER - A buck or boost converter, which includes a first inductor, a controlled switch, a main diode, and an output capacitor, also includes a snubber circuit to reduce losses. The snubber circuit includes a second inductor in a path in series with the switch and main diode of the converter, a series-connected resistor and diode connected directly in parallel with the second inductor, and a capacitance in parallel with the main diode and which can be constituted partly or entirely by parasitic capacitance of the main diode. | 10-29-2009 |
| 20090302813 | SUPPLY CIRCUIT WITH RIPPLE COMPENSATION - A supply circuit ( | 12-10-2009 |
| 20110043172 | Buck-Boost Converter With Smooth Transitions Between Modes - In a buck-boost converter, the method compensates for the boost mode power switch having a minimum on-time when entering the buck-boost mode from the buck mode by immediately decreasing a duty cycle of the buck mode power switch upon entering the buck-boost mode. This prevents the inductor current from being higher at the end of the switching cycle than at the beginning of the cycle, so the output voltage stays regulated without the converter oscillating between the buck mode and the buck-boost mode. The duty cycle of the buck power switch is increased in the buck-boost mode as the input voltage further falls and the boost power switch duty cycle is increased. Upon transitioning into the boost mode, the duty cycle of the boost power switch is immediately reduced to compensate for the buck switching being stopped and the buck power switch having a minimum off-time. | 02-24-2011 |
| 20140266086 | Coupled Inductors With Non-Uniform Winding Terminal Distributions - A coupled inductor includes a ladder magnetic core including two opposing rails extending in a lengthwise direction and joined by a plurality of rungs. The coupled inductor further includes a respective winding wound around each of the plurality of rungs. The plurality of rungs are divided into at least two groups of rungs, and a lengthwise separation distance between adjacent rungs in each group of rungs is less than a lengthwise separation distance between adjacent rungs of different groups of rungs. | 09-18-2014 |
| 323262000 | Plural windngs in series | 2 |
| 20090256535 | VARYING OPERATION OF A VOLTAGE REGULATOR, AND COMPONENTS THEREOF, BASED UPON LOAD CONDITIONS - A method for operating a voltage regulator controller, for use in a voltage regulator including coupled inductors, is provided as follows. A first signal is generated for driving a first switch of the voltage regulator. A second signal is generated driving a first switch of the voltage regulator. The voltage regulator determines whether a light-load condition exists. Upon determining the existence of a light-load condition, adjusting the phase difference between said first and second signals so that the first and second signals are approximately in-phase. | 10-15-2009 |
| 20140340057 | SYSTEM AND METHOD FOR REDUCING POWER CONSUMPTION IN A POWER SUPPLY CIRCUIT - A system for reducing power consumption in a power supply circuit including: a transformer including: a core; a first winding including a first end and a second end of a first wire wound on the core; a second winding including a first end and a second end of a second wire, wherein the second wire has a larger cross-section than the first wire and the second end of the first wire is connected to the first end of the second wire; an input electrically connecting the first and second windings to the power supply circuit; and an output for connecting to a load; and a controller connected to the transformer for controlling an output voltage at the output, wherein the output voltage is less than a supply voltage at the input, to reduce the power consumption of the load. | 11-20-2014 |
| 323263000 | With electronic tube or a three or more terminal semiconductive device in control circuit | 3 |
| 20080203981 | SEMICONDUCTOR DEVICE STRUCTURE AND SEMICONDUCTOR DEVICE INCORPORATING SAME - A semiconductor device structure includes a semiconductor substrate, a resistor layer, and a capacitor layer. The resistor layer is configured to overlie the semiconductor substrate. The resistor layer has a resistor disposed therewithin. The capacitor layer is configured to overlie the resistor layer. The capacitor layer has a capacitor disposed over and electrically connected with the resistor. Further, a semiconductor device that generates a constant output voltage from an input voltage includes a semiconductor substrate, a resistor layer, and a capacitor layer. The resistor layer is configured to overlie the semiconductor substrate. The resistor layer has a resistor disposed therewithin. The capacitor layer is configured to overlie the resistor layer. The capacitor layer has a capacitor disposed over and electrically connected with the resistor. | 08-28-2008 |
| 20090001945 | CIRCUIT AND METHOD FOR PHASE SHEDDING WITH REVERSE COUPLED INDUCTOR - In some embodiments, a regulator with a reverse coupled inductor is provided. It can operate in both a multi-phase and a phase shed mode. When in the phase shed mode, it has circuitry to provide a low resistance path for induced current. | 01-01-2009 |
| 20090167262 | POWER CONVERTER - A power converter ( | 07-02-2009 |
