Patent application number | Description | Published |
20090174257 | LARGE POWER MULTI-OUTPUTS POWER SUPPLY STRUCTURE HAVING RELATIVELY HIGH EFFICIENCY IN LOAD RANGE AND CONTROLLING METHOD THEREOF - The configurations of a switched-mode power supply and a controlling method thereof are provided. The proposed switched-mode power supply includes a first output converter receiving a DC input voltage and generating a first high power DC voltage output and at least one low power DC voltage output, and a second output converter receiving the DC input voltage and generating a second high power DC voltage output coupled to the first high power DC voltage output to generate a coupled output, wherein the first output converter works and the second output converter idles when a transient power of the coupled output is not larger than a rated output power of the first high power DC voltage output, and both the first and the second output converters work when the transient power is larger than the rated output power. | 07-09-2009 |
20090230929 | BRIDGELESS PFC CIRCUIT FOR CRM AND CONTROLLING METHOD THEREOF - The configurations of a bridgeless PFC circuit system and a controlling method thereof are provided. The proposed system includes a bridgeless PFC circuit having a first and a second input terminals, a first switch having a first terminal, a first inductor having a first terminal coupled to the first input terminal and a second terminal coupled to the first terminal of the first switch, and a second inductor having a first terminal coupled to the second input terminal, a first auxiliary winding coupled to the first inductor and generating a first sensing signal, and a second auxiliary winding coupled to the second inductor and generating a second sensing signal, wherein the first and the second sensing signals are used to generate an inductor current sensing signal controlling the switching of the first switch accordingly. | 09-17-2009 |
20100259957 | BRIDGELESS PFC CIRCUIT FOR CRITICAL CONTINUOUS CURRENT MODE AND CONTROLLING METHOD THEREOF - The configurations of a bridgeless PFC circuit and a controlling method thereof are provided. The proposed circuit includes an AC power source, a first and a second bridge arms, each of which has a middle point, wherein the first terminal of the first bridge arm connects the first terminal of the second bridge arm, the second terminal of the first bridge arm connects the second terminal of the second bridge arm, and the middle point of the second bridge arm connects the second terminal of the AC power source, a bidirectional switch module connected to the two middle points, an inductor having a first terminal coupled to the AC power source and a second terminal coupled to the middle point of the first bridge arm and a sensing circuit magnetically coupled to the inductor. | 10-14-2010 |
20110013436 | BRIDGELESS PFC CIRCUIT SYSTEM HAVING CURRENT SENSING CIRCUIT AND CONTROLLING METHOD THEREOF - The configurations of a bridgeless PFC circuit system and a controlling method thereof are provided. The proposed system includes a bridgeless PFC circuit including a first bridge arm having a first and a second terminals and a first middle point, a second bridge arm having a first and a second terminals and a second middle point, and a bidirectional switch coupled between the first middle point and the second middle point, and an inductor coupled between the first middle point and an AC power source coupled to the second middle point, and a current sensing circuit including a first current transformer sensing a first current flowing through the bidirectional switch, which having a primary side winding coupled to the bidirectional switch and a first and a second secondary side windings, and a switching device coupled to the two secondary side windings. | 01-20-2011 |
20110122662 | Buck and buck/boost converter systems having auxiliary circuits and method thereof - The configurations of a buck type and a buck/boost type converter systems and a controlling method thereof are provided in the present invention. The proposed buck/boost type converter system includes a rectifier bridge, a first auxiliary circuit including a first unidirectional switch coupled to the rectifier bridge and a second unidirectional switch coupled to the first unidirectional switch, a first capacitor coupled to the first unidirectional switch and the rectifier bridge, a buck/boost converter having a first input terminal coupled to the first unidirectional switch, a second input terminal coupled to the first capacitor, a first output terminal coupled to the second unidirectional switch and a second output terminal, a second capacitor electrically connected to the first and the second output terminals in parallel, and a DC source coupled to the second unidirectional switch. | 05-26-2011 |
20130121042 | CASCADED H-BRIDGE MEDIUM VOLTAGE DRIVE, POWER CELL AND BYPASS MODULE THEREOF - The present application relates to a cascaded H-Bridge medium voltage drive, a power cell, and a bypass module thereof, wherein the bypass module is configured for bypassing a major circuit module of the power cell, while the major circuit module comprises a fuse, a rectifier, a bus capacitor and an H-Bridge inverter, two points led from the H-Bridge inverter being configured as a first output end and a second output end; a bypass circuit comprises a first bridge arm and a second bridge arm; a point led from the first bridge arm is configured as a first input end of the bypass circuit, a point led from the second bridge arm is configured as a second input end of the bypass circuit, and the first input end is electrically connected with the first output end, the second input end is electrically connected with the second output end. | 05-16-2013 |
20130188401 | CAPACITOR DISCHARGING CIRCUIT AND CONVERTER - A capacitor discharging circuit and a converter are disclosed. The converter comprises: a capacitor connected between the live line and null line of an AC power input terminals, a conversion module coupled to the capacitor and comprising an energy storage component at least, an energy transfer unit coupled with the energy storage component and the capacitor, an AC power-off detecting unit and a control unit; wherein the energy transfer unit comprises a switch device; when AC power is disconnected, the AC power-off signal triggers the control unit to output a switch driving signal, controlling the operation of the energy transfer unit to transfer the energy stored in the capacitor to the energy storage component to discharge the capacitor. | 07-25-2013 |
20130188405 | CAPACITOR DISCHARGING CIRCUIT AND POWER CONVERTER - A capacitor discharging circuit and a power converter having the capacitor discharging circuit are disclosed. The capacitor discharging circuit comprises a conversion module connected with the two terminals of the capacitor, an AC power-off detecting unit used to detect on-off state of AC power, and a control unit. The conversion module comprises an energy consumption unit. When AC power is disconnected, the AC power-off signal generated by the AC power-off detecting unit intervenes the control unit to control the energy consumption unit to consume the energy stored in the capacitor. | 07-25-2013 |
20140085936 | VARIABLE FREQUENCY CONVERTER AND ADJUSTING METHOD FOR THE SAME - A variable frequency converter and an adjusting method for the same are provided in the present application. The variable frequency converter operates in a variable frequency mode, and comprises a power stage circuit module and a variable frequency signal stage circuit module which are connected to form a closed-loop circuit system. The variable frequency converter further comprises an adjusting unit outputting a continuous interfering signal and loading the continuous interfering signal into the variable frequency signal stage circuit module so as to cause operating frequency of the power stage circuit module controlled by the variable frequency signal stage circuit module to change continuously. In the present application, in the variable frequency converter, the EMI peak value is decreased. | 03-27-2014 |
Patent application number | Description | Published |
20120250356 | DC/DC CONVERTER, POWER CONVERTER AND CONTROL METHOD THEREOF - A DC/DC converter, a power converter and a control method thereof are disclosed, wherein the DC/DC converter includes an output circuit, a rectangular wave generator, a resonant tank, a detection unit and a control unit. The output circuit has a load. The rectangular wave generator converts an input voltage into driving pulses. The resonant tank provides a first voltage based on the driving pulses for the output circuit. The detection unit detects a signal related to a state of the load. When the state of the load is a light-load or a no-load, the control unit controls the rectangular wave generator in a hiccup mode to reduce a ratio of a work period to a stop period, or makes that number of the driving pulses within the current work period is less than the number of the driving pulses when a duty ratio is 50%. | 10-04-2012 |
20120250358 | DC/DC CONVERTER, POWER CONVERTER AND CONTROL METHOD THEREOF - A DC/DC converter, a power converter and a control method thereof are disclosed, where the DC/DC converter includes an output circuit, a rectangular wave generator, a resonant tank, a detection unit and a control unit. The output circuit has a load. The rectangular wave generator converts an input voltage into at least one rectangular wave. The resonant tank provides a first voltage based on the rectangular wave for the output circuit. The detection unit detects a signal related to a state of the load. When the state of the load is light-load or a no-load, the control unit controls a working frequency or a duty ratio of the rectangular wave, so that the duty ratio of the rectangular wave is within a predetermined range, in which a voltage gain of the DC/DC converter is greater than another voltage gain under the condition of 50% duty ratio. | 10-04-2012 |
20120250361 | DC/DC CONVERTER, POWER CONVERTER AND CONTROL METHOD THEREOF - A DC/DC converter, a power converter and a control method thereof are disclosed, where the DC/DC converter includes an output circuit having a load, a rectangular wave generator having a bridge arm, a resonant tank, a detection unit and a control unit. The bridge arm includes a first and a second switches connected each other. The detection unit detects a signal related to a state of the load. When the state of the load is a light-load or a no-load, the control unit controls ON/OFF state of the first and second switches by pulse width modulation mode to convert an input voltage into at least one rectangular wave for the resonant tank. A duty ratio of the first switch is within a first or second predetermined range, and a duty ratio of the second switch is complementary to the duty ratio of the first switch, whereby a voltage gain of the DC/DC converter is greater than 1. | 10-04-2012 |
20130082762 | POWER SWITCH SERIES CIRCUIT AND CONTROL METHOD THEREOF - The present invention provides a power switch series circuit and its control method. The power switch series circuit includes a plurality of series modules, a control module and a drive module. At least one series module has a power switch and a detection module, and the detection module includes a detection unit and an isolation unit, so as to detect the overvoltage and output a voltage detection signal based on the detected voltage. The control module receives the voltage detection signal and outputs the corresponding control signal. The drive module amplifies the control signal to drive each power switch to turn ON or turn OFF. The control module outputs the corresponding control signal to turn off each power switch when the overvoltage happens. | 04-04-2013 |
20130083485 | HEAT DISSIPATION APPARATUS FOR MEDIUM-VOLTAGE DRIVE - A heat dissipation apparatus is suitable for dissipating heat from heat-generating elements in a medium-voltage drive. The heat dissipation apparatus comprises: a heat-dissipating substrate, wherein the heat-generating elements are placed on at least one of a first surface and a second surface of the heat-dissipating substrate; at least one heat pipe group each of which includes a plurality of heat pipes, each heat pipe having an evaporation section and a condensation section, wherein the evaporation section is buried in an inner layer of the heat-dissipating substrate for absorbing heat from the heat-generating elements; and a plurality of fins arranged to be intersected with each heat pipe and connected to the condensation sections of the heat pipes, so as to transfer the heat released from the condensation sections to air. The contact portions between the heat pipe group and the fins are arranged in triangle staggered arrangements. | 04-04-2013 |
20130083576 | POWER SEMICONDUCTOR SWITCH SERIES CIRCUIT AND CONTROL METHOD THEREOF - The present disclosure provides a power semiconductor switch series circuit. The power semiconductor switch series circuit includes a plurality of series modules and a system control module. Each series module has a power semiconductor switch; a drive module for driving each power semiconductor switch to be turned on or turned off; a short-circuit detection unit for outputting at least one detection signal; an equalizer circuit; a comparison module for comparing the detection signal with a predetermined threshold, and outputting a short-circuit signal when the detection signal exceeds the predetermined threshold; and a soft turn-off module for receiving the short-circuit signal and outputting a second control signal. The system control module receives the short-circuit signal and outputs a first control signal. | 04-04-2013 |
20130100716 | HIGH-POWER MEDIUM-VOLTAGE DRIVE POWER CELL - The present invention provides a high-power medium-voltage drive power cell, which comprises: a rectifier module for rectifying the three-phase AC input voltage to get a DC voltage; an IGBT (Insulated Gate Bipolar Transistor) inverter bridge connected to capacitors for converting the DC voltage into an AC voltage of which the frequency, the amplitude and the phase are adjustable; a bypass module connected to the IGBT inverter bridge for providing the bypass function when the IGBT inverter bridge works in an abnormal state; and a heat pipe heat sink having a base plate on both sides of which power elements of the high-power medium-voltage drive power cell are disposed. | 04-25-2013 |
20130107458 | HEAT SINK DEVICE | 05-02-2013 |
20130176005 | DC/DC CONVERTER AND CONTROL METHOD THEREOF - The DC/DC converter includes a power unit, an output detection unit, a control unit and a compensation unit. The output detection unit detects an output stage of the power unit. The control unit provides a driving signal based on the output stage for the power unit to control the operation of the power unit. When the power unit operates in an intermittent working mode, the compensation unit provides a compensation signal for the control unit, and the control unit adjusts the driving signal according to the compensation signal, so that during at least one duty cycle an output power of the power unit in the intermittent working mode is higher than an output power of the power unit at a switching moment from a normal mode (continuous working mode) to the intermittent working mode, thereby when the load is not changed, the average number of driving signals is reduced. | 07-11-2013 |
20150155770 | FIVE-LEVEL RECTIFIER - Disclosed herein is a five-level rectifier that includes first, second, third, fourth power semiconductor switches, first and second DC bus capacitors, a phase capacitor, and first, second, third and fourth diode modules. The first, second, third and fourth diode modules are connected in series, the first and second DC bus capacitors are connected in series, and the second and third power semiconductor switches are connected in series. The first diode module is connected to the first DC bus capacitor and the first power semiconductor switch, and the fourth diode module is connected to the second DC bus capacitor and the fourth power semiconductor switch. The phase capacitor has a terminal connected to the first and second power semiconductor switches, and another terminal connected to the third and fourth power semiconductor switches. | 06-04-2015 |
20150340157 | DIRECT-CURRENT CAPACITOR MODULE AND LAMINATED BUSBAR STRUCTURE THEREOF - A direct-current capacitor module is disclosed in this disclosure. The direct-current capacitor module includes a plurality of direct-current capacitors and a laminated busbar structure. The direct-current capacitors are grouped into a first portion and a second portion. The laminated busbar structure is electrically connected to capacitor binding posts of the direct-current capacitors. The laminated busbar structure has a positive terminal and a negative terminal. The laminated busbar structure includes a first busbar layer, a second busbar layer and an insulation layer. The first busbar layer includes a first sub-busbar layer, which is electrically connected between at least two direct-current capacitors of the first portion. The second busbar layer includes a second sub-busbar layer, which is electrically connected between at least two direct-current capacitors of the second portion. The insulation layer is disposed between the first busbar layer and the second busbar layer. | 11-26-2015 |
20150340961 | POWER CONVERTER - The disclosure provides a power converter including a cabinet, a first converter circuit module, a second converter circuit module, and a DC capacitor module. The first converter circuit module includes at least one first bridge arm. The second converter circuit module includes at least one second bridge arm. The first converter circuit module, the second converter circuit module, and the DC capacitor module are disposed in the cabinet. The second bridge arm and the first bridge arm are arranged side by side in parallel. The DC capacitor module is electrically connected between the first bridge arm and the second bridge arm, so that the first bridge arm and the second bridge arm share the DC capacitor module. | 11-26-2015 |
20150340963 | THREE-LEVEL RECTIFIER - A three-level rectifier includes at least one phase bridge arm that includes an upper-half and a lower-half bridge arm circuit modules. The upper-half bridge arm circuit module includes a first diode unit and a second diode unit that are in series connection, and a first power semiconductor switch unit. The lower-half bridge arm circuit module includes a third diode unit and a fourth diode unit that are in series connection, and a second power semiconductor switch unit. These first and second power semiconductor switch units are connected to the neutral point of the capacitor unit; the second diode unit and the third diode unit are connected to the alternating-current terminal; the first diode unit and the fourth diode unit are respectively connected to the positive terminal and negative terminal of the direct-current bus. The two circuit modules are disposed side by side and facing each other. | 11-26-2015 |
20150346276 | CONVERTER CIRCUIT AND OPEN-CIRCUIT DETECTION METHOD OF THE SAME - A converter circuit is provided. The converter circuit includes a capacitor module, bridge arms, a voltage measuring module and an open-circuit detection module. Each bridge arm is connected to the capacitor module in parallel and includes an upper arm and a lower bridge arm connected at a middle point. The voltage measuring module measures voltage differences between each two bridge arms. The open-circuit detection module transmits test impulse signals to the bridge arms to activate at least one upper-conducted bridge arm and at least one lower-conducted bridge arm. The open-circuit detection module retrieves the voltage differences of each pair of the upper-conducted and lower-conducted bridge arms to make comparison with a reference value to determine an operation state thereof, and makes comparison of the operation state determined according to the different groups of test impulse signals to determine whether the upper and the lower bridge arms are actually open circuit. | 12-03-2015 |
20150349521 | SHORT- CIRCUIT DETECTION DEVICE AND METHOD USED IN INVERTER CIRCUIT - A method for detecting a short circuit fault in a multi-level inverter circuit is provided. The multi-level inverter circuit includes a plurality of single phase branches each including of switches. The method includes steps outlined below. At least one detecting pulse sequence is transmitted to the switches of each of the single phase branches. Whether a conducting path is formed in any of the single phase branches is determined according to the detecting pulse sequence. When the conducting loop is formed, respective position of one or more malfunctioned switch in the single phase branches is located according to a path of the conducting loop. A short-circuit detection device and a three-phase three-level inverter circuit are also disclosed herein. | 12-03-2015 |
20150349654 | VOLTAGE-ADJUSTING DEVICE AND METHOD IN POWER CONVERSION SYSTEM - The present disclosure provides a voltage-adjusting device applied in a power conversion system including a Vienna rectifier, a direct current (DC) bus, and an inverter. The voltage-adjusting device includes a grid voltage sampling module for sampling a grid voltage, a given bus voltage calculation module, a voltage-adjusting module, a current control module and a pulse width modulation module. The given bus voltage calculation module calculates a given value of the DC bus voltage based on the grid voltage. The current control module receives a three phase AC current from the grid, the active current given signal and the reactive current given signal to output a three phase control voltage. The pulse width modulation module outputs a pulse control signal to the Vienna rectifier. | 12-03-2015 |
20150349681 | VARIABLE FREQUENCY SPEED CONTROL SYSTEM AND METHOD OF THE SAME - A variable frequency speed control system having a low voltage ride through function that includes a variable frequency drive having a rectifier, a DC bus and an inverter is provided. The variable frequency speed control system includes a voltage drop detecting module, a frequency control module, an operation mode selecting module and an inverter control module. The voltage drop detecting module generates a voltage drop coefficient according to a grid voltage and a rated grid voltage and generates an operation mode switching signal. The operation mode selecting module receives a target frequency signal and a frequency decreasing amount and generates an output frequency signal according to the operation mode switching signal. The inverter control module generates a three phase modulating signal according to the output frequency signal, which is used to control the operation of the inverter. | 12-03-2015 |
20150362528 | VOLTAGE SAMPLING SYSTEM - A voltage sampling system is provided. The voltage sampling system includes a voltage sampling device, two optic-fiber transmission lines and a control device. The voltage sampling device includes a voltage-dividing resistor module, a common mode rejection circuit and an analog-to-digital converter. The voltage-dividing resistor module generates a first and a second divided voltages according to a voltage source. The common mode rejection circuit receives the first and the second divided voltages to perform a common-mode noise rejecting process to generate an output voltage. The analog-to-digital converter converts the output voltage to generate a digital data signal. The two optic-fiber transmission lines transmit the digital data signal and a clock signal respectively. The control device receives the digital data signal from the analog-to-digital converter and the clock signal to perform a digital data processing. | 12-17-2015 |
20150362529 | POWER CONVERSION SYSTEM AND VOLTAGE SAMPLING DEVICE THEREOF - A voltage sampling system is provided. The voltage sampling system includes a first and a second input paths and a signal-processing module. The first input path includes a first input voltage-dividing resistor unit, a second input voltage-dividing resistor unit and a first DC voltage-dividing resistor unit to generate a first input divided voltage and a first DC bias voltage to further generate a first sampled voltage signal according to a first input voltage and a DC voltage source. The second input path includes a third input voltage-dividing resistor unit, a fourth input voltage-dividing resistor unit and a second DC voltage-dividing resistor unit to generate a second input divided voltage and a second DC bias voltage to further generate a second sampled voltage signal according to a second input voltage and the DC voltage source. The signal-processing module receives the first and the second sampled voltage signals to perform signal processing. | 12-17-2015 |
Patent application number | Description | Published |
20120274384 | SEMICONDUCTOR DEVICE - The present invention discloses a semiconductor device and relates to the semiconductor field. The semiconductor device comprises: a PMOS transistor for processing a input signal, the PMOS transistor comprising a gate and a source, the source being connected to a first voltage source; and a restoring circuit connected to the PMOS transistor for preventing degradation of the PMOS transistor, wherein the restoring circuit makes the gate voltage of the PMOS transistor to be higher than the voltage of the first voltage source, when the input signal is at a high level. According to the semiconductor device of the present invention, a positive bias voltage is applied on the gate of the PMOS transistor through the restoring circuit when the PMOS transistor is turned off, which can accelerate electric parameter recovery for PMOS transistors and therefore improve the performance of PMOS transistors. | 11-01-2012 |
20130341642 | MOS TRANSISTOR, FABRICATION METHOD THEREOF, AND SRAM MEMORY CELL CIRCUIT - Various embodiments provide an MOS transistor, a formation method thereof, and an SRAM memory cell circuit. An exemplary MOS transistor can include a channel region including an asymmetric stressing layer having a stress gradually varied from a compressive stress to a tensile stress or from a tensile stress to a compressive stress from a first end of the channel region adjacent to a source region to a second end of the channel region adjacent to a drain region. The MOS transistor can be used as a transfer transistor in an SRAM memory cell circuit to increase a source-drain saturation current in a write operation and to reduce a source-drain saturation current in a read operation. Read and write margins of the SRAM can be increased. | 12-26-2013 |
20130341726 | MOS TRANSISTOR, FORMATION METHOD THEREOF, AND SRAM MEMORY CELL CIRCUIT - Various embodiments provide an MOS transistor, a formation method thereof, and an SRAM memory cell circuit. An exemplary MOS transistor can include a semiconductor substrate including a first groove on one side of a gate structure and a second groove on the other side of the gate structure. The first groove can have a sidewall perpendicular to a surface of the semiconductor substrate. The second groove can have a sidewall protruding toward a channel region under the gate structure. A stressing material can be disposed in the first groove to form a drain region and in the second groove to form a source region. Stress generated in the channel region of the MOS transistor can be asymmetric. The MOS transistor can be used as a transfer transistor in an SRAM memory cell circuit to increase both read and write margins of the SRAM memory. | 12-26-2013 |
20140015136 | IC DEVICE INCLUDING PACKAGE STRUCTURE AND METHOD OF FORMING THE SAME - Various embodiments provide semiconductor devices including a package structure and methods of forming the semiconductor devices. In one embodiment, the package structure can include a through-hole at least partially filled by one or more layers of material(s) to form a through-hole interconnect between semiconductor devices in the package structure. The through-hole can be filled by an insulating layer, a diffusion barrier layer, a metal interconnect layer, and/or a protective layer having a total thickness from the sidewall of the through-hole of less than or equal to the radius of the through-hole. | 01-16-2014 |
20140361400 | ELECTROSTATIC DISCHARGE PROTECTION STRUCTURE AND METHOD FOR FORMING THE SAME - Various embodiments provide electrostatic discharge protection structures and methods for forming the same. An exemplary structure can include a semiconductor chip including a through hole. The structure can further include a through silicon via (TSV) structure disposed within the through hole and passing through the semiconductor chip. The TSV structure can have a first surface and a second surface. The structure can further include a tunneling dielectric layer disposed on the first surface of the TSV structure. The tunneling dielectric layer can have a surface area covering a top view surface area of the TSV structure and a surface portion of the semiconductor chip surrounding the TSV structure. Yet further, the structure can include a metal material discretely dispersed in the tunneling dielectric layer, a first electrode disposed on the tunneling dielectric layer, and a second electrode disposed on the second surface of the TSV structure. | 12-11-2014 |
20150311313 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD THEREOF - A method of manufacturing a semiconductor device is provided. The method includes providing a substrate; forming a well region on the substrate; forming at least one first gate structure on the well region, wherein the first gate structure includes a gate insulating layer and a first gate electrode formed on the gate insulating layer, wherein the first gate electrode is formed having a first enclosed pattern on a surface of the well region; wherein an area inside the first enclosed pattern is defined as a first region, and an area outside the first enclosed pattern is defined as a second region; performing ion implantation on the first region such that the first region has a first conductivity type, and performing ion implantation on the second region such that the second region has a second conductivity type, wherein the first conductivity type and the second conductivity type are different. | 10-29-2015 |