Abstract: Disclosed therein is a stator assembly, which includes a circular base part and a stator core having a plurality of teeth radially formed on an outer face of the base part and respectively having a tooth end portion. The stator assembly further includes: a magmate holder including a base plate, at least one inner leg and at least one outer leg formed at a lower portion of the base plate, and a power connector part formed on an upper portion of the base plate and having a joining projection formed at one side thereof; and a sensor cover including a body part and a hook formed on a lower portion of the body part and being joined with the joining projection.

Abstract: A brushless motor includes a stator comprising a stator core with teeth protruding inwardly and windings wound on the teeth, and a rotor comprising a shaft, a rotor core fixed to the shaft, and a ring magnet fixed to the circumferential outer surface of the rotor core. The ring magnet includes a plurality of magnetic poles radially magnetized so that north poles and south poles are arranged alternately in the circumferential direction, boundary lines between adjacent magnetic poles being skewed by an angle ? relative to an axis of the shaft. A plurality of grooves are formed in a circumferential outer surface of the rotor core. Each groove extends from one axial end to the other axial end of the rotor core, has a circumferential width smaller than each of the magnetic poles, and is covered by the ring magnet with a void formed between the groove and the ring magnet.

Abstract: A commutated DC motor (10) includes a stator (12) and a rotor (14) mounted in the stator (12). The stator (12) has 2P magnetic poles, wherein P is an integer greater than 1. The rotor (14) includes a rotor shaft (81) with a rotor core (85), and a commutator (83) fixed thereto. The rotor core (85) has multiple teeth defining m×P slots therebetween, wherein m is an odd integer greater than 1. The commutator (83) has k×m×P segments, wherein k is 1 or 2. A rotor winding (87) formed by winding a single continuous wire is received in the slots of the rotor core (85) and connected to the segments of the commutator (83), and has k×m winding units. Each winding unit includes P coils in series connection and is directly connected to only two segments.

Abstract: A multi-gap rotating electric machine includes a rotor, a stator core and a stator coil. The stator core has inner and outer core parts respectively located radially inside and outside of the rotor and each having partially or fully closed slots. The stator coil is formed of electric conductor segments each having a first leg portion inserted in one of the slots of the inner core part, a second leg portion inserted in one of the slots of the outer core part, and a connecting portion connecting the first and second leg portions on one axial side of the rotor. The first and second leg portions respectively have radially inner and outer coil end parts formed on the opposite axial side to the connecting portion. Corresponding radially inner coil end parts are joined to each other, and corresponding radially outer coil end parts are joined to each other.

Abstract: A permanent magnet motor in which electromagnetic excitation force of low spatial order is reduced, and influence of a magnetomotive force harmonic of a rotor and torque ripple is reduced. One set of armature windings receives current from a first inverter, and another set of armature windings receives current from a second inverter. Where a pole number of a rotor is M and the number of slots of a stator core is Q, M and Q satisfy M<Q and a greatest common divisor of M and Q is equal to or greater than 3. In the rotor, the iron core is located beyond a radius intermediate the maximum outer radius and the minimum inner radius of the permanent magnets. A phase difference between three-phase currents from the first and second inverters is in a range of electrical angles of 20 to 40 degrees.

Abstract: A stator for an electric motor includes a plurality of pole pieces and a plurality of electrical windings associated with the pole pieces. Each winding includes a cable having an electrically conductive element. A lossy insulative material is located between the electrical windings and the associated pole pieces.

Abstract: A radial lead seal assembly of a generator and a method for sealing a radial chamber from an axial chamber of a generator using a radial lead seal assembly are presented. The radial lead seal assembly includes sealing elements disposed around a radial lead to seal an annular space between the radial lead and the radial chamber and thereby seal the axial chamber fluidically from the radial chamber. Conical springs are disposed annularly around the radial lead between the sealing elements and a junction between the radial lead and the axial lead. The radial lead seal assembly includes a nut for exerting a compressive load on the radial lead seal assembly in a radially inward direction such that the conical springs are only partially compressed.

Abstract: A motor apparatus provided with a connector unit (40) to which an external connector is connected, wherein the connector unit (40) has a plurality of conductive members (64, 65, 66) arranged over a base portion (50) and a connector connecting portion (70) provided with a plug-in hole in which the external connector is plugged, wherein the conductive members (64, 65, 66) respectively include connector-side connecting portions (64a, 65a, 66a) connected to the external connector so as to face the connector connecting portion (70) from a first direction reversed to a plug-in direction of the external connector to the plug-in hole and base-side connecting portions (64b, 65b, 66b) connected to terminals or wirings provided in the base portion (50), wherein the connector-side connecting portions (64a, 65a, 66a) are respectively inserted into a plurality of insertion holes (74, 75, 76) provided at positions different from each other in a second direction intersecting the first direction, and wherein the base-side con

Abstract: An electromechanical actuator device (17) and method for use under water in petroleum activity, in which, via a transmission element (30, 34, 36), an electric motor (18), including a stator (20) and a rotor (22), is arranged to move an actuation element (36) between at least a first position and a second position, and in which the rotor (22) of the electric motor (18) surrounds and is connected to an actuator nut (30) which is in threaded engagement with the actuation element (36).

Abstract: Driver for a turbine generator aided by magnetic levitation to enhance support without increasing friction. In one aspect, an apparatus includes an outer circular structure with a magnetic rail structure, an inner circular structure with a second magnetic rail structure, wherein the circular structures are magnetically levitated and freely rotational with respect to each other. The inner circular structure being mechanically coupled to a generator rotor so when the inner circular structure rotates, it imparts a rotational force on the generator rotor. In another aspect, the inner circular structure is rigidly fixed to an armature of a generator. In another aspect, the mechanical coupling comprises a plurality of turbine blades and/or a plurality of gear surfaces.

Abstract: When an electromagnetic generator 10 having a pendulum structure is mounted on an interior surface of a tire 20, an equivalent pendulum length l of a pendulum 14 is adjusted such that an integral multiple of a period ? of the pendulum 14, which is determined by the equivalent pendulum length l of the electromagnetic generator 10, is not in agreement with both of an integral multiple of a circumferential length L of the tire 20 and a length S of a non-grounded part of the tire, which is obtained by subtracting a ground contact length C from the circumferential length L of the tire 20, whereby the power generation capacity of the electromagnetic generator mounted on the tire can be improved regardless of the type of the tire.

Abstract: A motor cooling structure for cooling a motor, which includes a shaft transmitting power and a rotor core attached to an outside of the shaft, by a cooling medium, includes: a cooling medium supply passage that extends to an inside of the shaft in an axial direction of the shaft and passes the cooling medium through the cooling medium supply passage; and a plurality of cooling medium passages that are branched from the cooling medium supply passage to cool the rotor core while flowing the cooling medium without branching the cooling medium in the axial direction and then eject the cooling medium from a plurality of ejection holes opened to a surface of the rotor core, wherein distances from a cooling medium inlet, through which the cooling medium flows into the cooling medium supply passage, to the respective ejection holes are equal between the plurality of cooling medium passages.

Abstract: Provided is an electric drive apparatus in which a detected portion (10) of a rotation angle sensor is disposed at an end of a shaft (7) of a motor, and a sensor portion (300) as a detection portion of the rotation angle sensor is disposed coaxially with the rotating axis of the shaft. In a control unit (200), an inverter circuit portion with a drive element (SW) for driving the motor, and a control substrate (17) which is separate from the sensor portion and controls the output of the inverter circuit portion are disposed. The sensor portion and the control substrate are electrically connected, with the control substrate disposed along a plane perpendicular to the rotating axis of the shaft.

Abstract: Systems and methods for preventing electrical arcing in motors by placing an electrically conductive roller assembly between the stator and rotor of the motor. A rotor is mounted on a shaft, and this assembly is positioned within the bore of a stator. The roller assembly has a stationary portion that is secured to the stator. The roller assembly also has a movable portion on which a roller is mounted. The movable portion of the roller assembly is spring-loaded to urge the roller toward the shaft and thereby maintain contact between the roller and the shaft. When the shaft rotates within the bore, the roller rotates and rolls on the surface of the shaft, maintaining contact without rubbing against the shaft. An electrically conductive pathway is formed from the stator, through the roller assembly to the shaft and rotor thereby preventing an electrical potential from developing between the rotor and stator.

Abstract: A lead wire connection structure includes a rectifier that is arranged at the outside or the inside in an axis direction of the brackets so as to rectify AC voltage, which is generated on the stator, to DC voltage; in which, when a number of conductors of a connecting portion, at which lead conductors of the stator winding and the rectifier are connected, is “N” (N is integer and greater than or equal to 2) per one position, conductors, of which number is less than or equal to “N?1” per one position, are connected at the connecting portion, and conductors excepted from the conductors, of which number is less than or equal to “N?1”, are welded onto the remaining conductors at a position being nearer the stator winding side than the connecting portion.

Abstract: A circuit board is held by a holding member. A connector portion is located on an opposite side of the circuit board from the holding member. A connector terminal is projected from a portion of the peripheral wall portion, bent at a bent portion toward the circuit board, and connected with the circuit board. The connector terminal includes a projected portion, which is located closer to the peripheral wall portion than the bent portion, and an inserted portion, which is inserted in a through hole of the circuit board. The projected portion is shifted from the inserted portion when viewed from a side of the connector portion.

Abstract: An electronics package for an alternator includes an electrically conductive carrier member and a terminal assembly engaging the carrier member. The carrier member includes an inner side, an outer side, and at least one passage extending from the inner side to the outer side. A plurality of switches are connected to the carrier member. The terminal assembly includes an electrically insulative portion and a plurality of electrical traces extending through the electrically insulative portion. The electrically insulative portion includes a post extending through the at least one passage of the carrier member, a first shoulder engaging the outer side of the carrier member, and a second shoulder engaging the inner side of the carrier member. The post, the first shoulder, and second shoulder are all formed as a unitary component.

Abstract: A method of vertically assembling a generator of a wind turbine is provided. The method includes A rotor part is arranged on a horizontal assembly which supports components of the generator such that a rotational axis of a component is essentially vertical during assembly, and the assembly support is configured to allow access to an interior of a generator component during the assembly procedure; a stator part is arranged in the rotor part; and the stator part is joined to the rotor part. An assembly arrangement for a vertical assembly of a generator of a wind turbine is provided. The assembly arrangement includes a horizontal assembly support for supporting components of the generator such that a rotational axis of a component is essentially vertical during assembly, and the assembly support is configured to allow access to an interior of a generator component during the assembly procedure.

Abstract: A method of servicing a stator frame of a power generator. The method includes removing a first stator core from a main housing of the stator frame, removing a plurality of first dove-tail shaped keybars that extend axially within and are coupled to a main support structure forming part of the main housing, and installing a plurality of second keybars in the main support structure in place of the first dove-tail shaped keybars. The second keybars are adapted to support a second stator core. Each of the second keybars has a generally rounded engagement surface and the second stator core includes recesses with shapes corresponding to the generally rounded engagement surfaces of the second keybars such that the second stator core can be securely supported in the main support structure by the second keybars.

Abstract: A power system with regeneration may include an electric power storage element, an electric motor in electrical communication with the electric power storage element, a rotatable shaft operably coupled to the electric motor for rotation by the electric motor and adapted to provide rotational energy to a power take-off device, and a regeneration component operably coupled to the rotatable shaft and adapted for converting rotational energy of the shaft to electrical energy, the regeneration component being in electrical communication with the electric power storage element and adapted to recharge the electric power storage element.

Abstract: An apparatus (100), including: a pendulum (102) having a pendulum magnet arrangement; a stationary magnet (118, 122) positioned such that a magnetic field of the stationary magnet repels the pendulum magnet as it approaches the stationary magnet; a magnetic shielding apparatus (126, 128) configured to intermittently shield the stationary magnet from the pendulum magnet; and a power source configured to supply power to the magnetic shielding apparatus. The magnetic shielding apparatus is configured to shield the stationary magnet from the pendulum magnet as the pendulum magnet approaches an apex position (16, 42) of a cycle. As the pendulum, magnet arrangement recedes from the apex position a repulsion associated with an interaction of a fully unshielded magnetic field of the stationary magnet and a magnetic field of the pendulum magnet arrangement is effective to accelerate the pendulum.

Abstract: A turbine is provided having one or more vanes joined to respective balloons. Compressed or pumped gas entering the turbine is selectively directed toward desired balloons by selectively activating one or more input valves, in order to selectively inflate the balloons. Simultaneously, gas inside the balloons is selectively directed away from the balloons and out of the turbine by selectively activating one or more output valves, in order to selectively deflate the balloons. The turbine is configured for being at least partially submerged in a liquid. The selective inflation of the balloons generates buoyancy which pushes the balloons upward, thereby causing the turbine to rotate. The selective deflation of the balloons decreases buoyancy which may counter the turbine's rotation. The turbine's rotation can be converted to a desired form of energy via a suitable energy converter.

Abstract: A buck power converter creates a desired output voltage from a greater input voltage with higher efficiency than linear regulators or charge pumps. For compact-size and cost sensitive products, the use of the buck power converter is hindered mainly because of lack of physical space and increases in the cost of the passive components like the inductor and capacitor. Techniques are presented to reduce the sizes of the passive components so that they can be integrated on-chip or in-package or on board. A signal converter in the buck power converter determines the duty cycle of a switching control signal. The switching control signal would ordinarily have driven a power switching circuit that provides current to the inductor in the buck power converter. The signal converter outputs a modified (multiphase) switching control signal that includes multiple separated on-periods that taken together approximate the duty cycle of the switching control signal while maintaining the same control loop frequency.

Abstract: A semiconductor module is provided with a high potential wiring, an output wiring, a low potential wiring, an upper arm switching device, an upper arm diode, a lower arm switching device, and a lower arm diode. A ratio of steady loss to switching loss of the upper arm switching device is configured to be smaller than a ratio of steady loss to switching loss of the lower arm switching device. Further, a ratio of steady loss to switching loss of the upper arm diode is configured to be smaller than a ratio of steady loss to switching loss of the lower arm diode.

Abstract: A ride-through and recovery method for DC short circuit faults of a hybrid modular multilevel converter based high-voltage direct current transmission (MMC-HVDC) system, the hybrid MMC including multiple full-bridge sub-modules and half-bridge sub-modules, and the method including: 1) detecting whether a DC short circuit fault occurs, and proceeding to step (2) if yes and continuing detecting if no; 2) realizing ride-through of the DC short circuit fault; 3) detecting whether a DC residual voltage increases, and proceeding to step (4) if yes and continuing detecting if no; and 4) realizing DC short circuit fault recovery.

Abstract: A power conversion device implementing an electrical-path-cutoff only if a power semiconductor element short-circuits, and to implement the cutoff at a timing earlier than when a battery fuse fuses, includes a pair of power semiconductor elements configured to be an upper arm element and a lower arm element, being connected in series between a positive-polarity electrode and a negative-polarity electrode; a short circuit detection circuit configured to detect a short circuit in the lower arm element; switching element for fusing, configured to be disposed between positive-polarity-side terminal of upper arm element on the positive-polarity electrode side, and negative-polarity-side terminal of lower arm element on the negative-polarity electrode side, and to be driven to have the positive-polarity-side terminal connected with the negative-polarity electrode when the short circuit is detected; and a cutoff part configured to be made of thin metallic wire for having the negative-polarity-side terminal connected

Abstract: A method for changing a capacitance value of an output capacitor of a power factor corrector (PFC) includes applying AC power to a power conversion circuit. It is sensed whether an instantaneous power failure occurs in the AC power. Output capacitors of the PFC of the power conversion circuit are connected in parallel to each other to increase capacitance values of the output capacitors, when it is sensed that the instantaneous power failure does not occur in the AC power.

Abstract: A switch power converter and method of testing and adjusting is provided. A switch power unit comprises at least a power switch for transform of the power. A controller is configured to generate a control signal for the power switch. A detector is configured to detect an output voltage signal and/or an output current signal of the switch power unit and output a sampling signal. A testing and adjusting unit is configured to receive the sampling signal and output a testing signal to the controller. The testing and adjusting unit comprises a compensator. The compensator attends the testing and adjusting of the switch power converter.

Abstract: A load voltage control device, comprising: a load disposed in a tip portion; a power supply circuit and a controller disposed in a proximal end portion; and a cable connecting the tip portion with the proximal end portion, the cable comprising a first and second power supply lines, the power supply circuit comprising at least one power supply, wherein the controller operates to: obtain a voltage applied to the load based on a voltage applied to an input point of the first power supply line, a current flowing through the first power supply line, a voltage applied to an input point of the second power supply line and a current flowing through the second power supply line; and adjust the power supply voltage by controlling the at least one power supply so that the voltage applied to the load becomes substantially equal to a predetermined reference voltage.

Abstract: A mixed power supply device includes a power supply component for providing a DC voltage; a DC-DC conversion module coupled to the power supply component to receive the DC voltage and output a stable DC voltage; a current transformation module coupled between the DC-DC conversion module and a load to receive the stable DC voltage and convert the stable DC voltage into an AC voltage; and a merging network switching switch coupled to the current transformation module to connect the current transformation module and a utility power network in parallel or disconnect the current transformation module from the utility power network, allowing a load to receive merging network mode-based power supply or standalone mode-based power supply, wherein, in the merging network mode, the current transformation module performs unbalanced current compensation on load unbalance of the load.

Abstract: A fast blocking switch includes, for example, an energy storage device, a first power switch and a second power switch. The energy storage device stores a charge for fast activation of the switches. The first switch is operable for coupling input current to an output terminal in response to the coupling of a potential supplied by the stored charge to a control terminal of the first switch. The second switch is operable for coupling a limited amount of the input current to the output terminal in response to the coupling of a potential supplied by the stored charge to a control terminal of the second switch.

Abstract: A voltage generation circuit is provided to suppress the required layout of the voltage generation circuit and stabilize the output voltage thereof. [Solution] A voltage generation circuit 100A according to the present invention includes a charge pump circuit 20, a resistor voltage-division circuit 120, a comparator 34 having a voltage Vm output from the resistor voltage-division circuit 120 and a reference voltage, and a control circuit 36 controlling the operation of the charge pump circuit 20 based on the comparison result of the comparator 34. The resistor voltage-division circuit 120 includes resistors R1˜R4 connected in series between an output node NOUT and a ground and generates the voltage Vm at a voltage-division node NR in response to an output voltage VOUT. The resistor voltage-division circuit 120 further includes a parasitic capacitor Cp to capacitively couple the resistors R1, R2, R3 and R4 to the output node NOUT.

Abstract: A voltage recovery circuit in an integrated circuit is provided. The voltage recovery circuit includes a bootstrap circuit coupled to a cascode switch circuit. The bootstrap circuit includes a first transistor coupled in series to a second transistor, a resistive element is coupled between the second transistor and an output of the voltage recovery circuit, and a capacitive element is coupled between control electrodes of the first and second transistors and the output. The cascode switch circuit includes a third and fourth transistor coupled in series. The third transistor includes a current electrode coupled to receive a first input voltage, and a control electrode coupled to the control electrodes of the first and second transistors. The fourth transistor includes a current electrode coupled to the output, and a control electrode coupled to a current electrode of the second transistor and a terminal of the resistive element.

Abstract: A power converter includes a DC/DC converting circuit and a first energy storage element. The DC/DC converting circuit includes a first output terminal and a second output terminal. The first energy storage element includes a first terminal and a second terminal. The first output terminal of the DC/DC converting circuit is electrically connected to one terminal of an external load. The first terminal of the first energy storage element is electrically connected to the second output terminal of the DC/DC converting circuit. The second terminal of the first energy storage element is electrically connected to the other terminal of the external load. The DC/DC converting circuit is configured to provide a variable electric power. The power converter provides the power supply according to the DC/DC converting circuit and the first energy storage element, and the variable electric power is less than the power required by the external load.

Abstract: There are disclosed herein various implementations of a power converter having an advanced control integrated circuit (IC). The power converter includes the control IC and a power switch. The control IC includes a driving stage for driving the power switch, and a sensing stage coupled to the driving stage. The sensing stage is configured to produce a control signal for the driving stage based on an output current of the power converter sensed at a high side bus of the power converter.

Abstract: One embodiment of a power management system includes a reservoir configured to collect energy. The system also includes a voltage regulator coupled to the reservoir via an input terminal and configured to convert the energy to an output voltage via an output terminal when enabled. A threshold detector is coupled to the reservoir and is configured to sense the energy and enable the voltage regulator when the energy exceeds a threshold. The system further includes a feedback circuit coupled between the output terminal and the threshold detector, and configured to feedback the output voltage to the threshold detector to compensate for a voltage drop across the threshold detector due to an output current drawn by the load.

Abstract: A step-down chopper type switching power-supply device includes a step-down chopper circuit including an inductor connected to a switching element connected to a DC power source, a regenerative-voltage detecting circuit, a control circuit controlling the switching element such that regenerative voltage becomes a reference voltage, an auxiliary power supply circuit charging a capacitor by using the regenerative voltage and supplying the voltage of the capacitor as power-supply voltage to the control circuit, and a activation circuit stopping supply of current to the capacitor after activation of the auxiliary power supply circuit, wherein, after activation of the auxiliary power supply circuit, in a case where voltage supplied from the DC power source is equal to or less than a first threshold value, the activation circuit performs control by the voltage supplied from the DC power source, such that current is supplied to the capacitor.

Abstract: A current estimation method for a switching voltage regulator that delivers current to a load through an inductor includes measuring a voltage across a capacitor of an RC current sense network coupled in parallel with the inductor, generating an estimate of the current through the inductor based on the voltage measured across the capacitor of the RC current sense network and adjusting the estimate of the current through the inductor by a compensation filter that compensates for variation in the inductance of the inductor as a function of at least one of temperature and current.

Abstract: A voltage converter (10) comprises a converter input (11), a coil (13) with a first and a second coil terminal (14, 14?), a first switch (15) arranged between the first coil terminal (14) and a reference potential terminal (16), a second switch (17) arranged between the converter input (11) and the first coil terminal (14), a converter output (12) coupled to the second coil terminal (14?) and a control unit (18). The control unit (18) is configured to set the first switch (15) into a blocking state in a first phase (A) of an operating mode of the voltage converter (10) and into a diode mode in a second phase (B) of the operating mode of the voltage converter (10) and to set the second switch (17) into a conducting state in the first phase (A) and into a blocking state in the second phase (B).

Abstract: Devices, systems, and methods for monitoring overcurrent and zero voltage are disclosed. These devices, systems, and methods monitor an input/output pin of an electronic device to determine a period of time when monitoring for an overcurrent of the input/output pin of the electronic device is not performed and compare a first input voltage to a first reference voltage during the period of time when monitoring for the overcurrent of the input/output pin of the electronic device is not performed so as to determine when a diode is conducting current, the diode being located across a switch being monitored for a zero voltage state, wherein the diode conducting current indicates that the switch is at the zero voltage state.

Abstract: An embodiment power converter package comprises a semiconductor die, an output inductor, a plurality of input capacitors and output capacitors. The semiconductor die, the output inductor and the plurality of capacitors are mounted on a lead frame and connected one to another through various pads on the lead frame. The semiconductor die comprises a high side switch, a low side switch and a driver. The power converter package is electrically coupled to an external pulse width modulation controller through a variety of input and output pads.

Abstract: A highly efficient and low-cost switching power supply device includes a high withstand voltage transistor and a low withstand voltage transistor. When current flows from a second node to a first node, the high withstand voltage transistor turns on and the low withstand voltage transistor turns off, causing current to flow through a built-in diode of the low withstand voltage transistor. Since current does not flow through the parasitic diode of the high withstand voltage transistor, the recovery current is reduced. Furthermore, since a first delay circuit including resistors and a diode is connected to the gate electrode of the high withstand voltage transistor, and a second delay circuit including resistors and a diode is connected to the gate electrode of the low withstand voltage transistor, precise adjustment of the switching speed during switching operation is possible, and losses are reduced.

Abstract: A voltage regulator circuit includes: a comparator configured to have a first input coupled to an output voltage of the voltage regulator circuit; a second input coupled to a reference voltage and an output signal; a first transistor; a second transistor, a drain of the first transistor connected to a drain of the second transistor; an inductor connected to the drain of the first transistor and the drain of the second transistor; a capacitor and a resistor connected in parallel, between the output node and a source of the second transistor; a peak-current detector unit configured to detect peak current in the inductor; a zero-crossing detector unit configured to detect a zero-crossing current in the inductor; and a control unit configured to receive a plurality of input signals including at least an input voltage and a clock signal.

Abstract: The present disclosure provides a modulated power supply system having a switching converter with an output terminal for supplying modulated power to a load. The modulated power supply system also includes a controller adapted to transition the switching converter between a buck mode and a boost mode in response to a detection of at least one predetermined condition associated with the output terminal.

Abstract: A power supply system includes a power source; a load device configured to receive power from the power source; and a power interface device coupled to the power source and the load device and configured to change a first voltage provided by the power source to a second voltage for operating the load device. The power interface device include a main switching converter configured to operate at a first switching frequency and source low frequency current to the load device and an auxiliary switching converter coupled in parallel with the main switching converter and configured to operate at a second and different switching frequency and source fast transient high frequency current to the load device.

Abstract: A quasi-resonance switching power supply quickly determines the number of bottom skips corresponding to the load condition even in abrupt load change. The quasi-resonance switching power supply is provided with a bottom skipping control function and a capacitor to hold a voltage corresponding to the load condition of the switching element over one switching period of the switching element. The quasi-resonance switching power supply comprises a bottom skipping number determining circuit that compares the voltage held on the capacitor with comparison reference voltages selected from a plurality of reference voltages for determining the number of bottom skips, and revises the comparison reference voltage according to the comparison result. The processing of comparison and revision is executed multiple times in one switching period of the switching element. Thus, the bottom skipping number determining circuit determines the number of bottom skips corresponding to the voltage held on the capacitor.

Abstract: A circuit arrangement is disclosed for ascertaining switching times for a DC-DC voltage converter which has an actuating unit, configured to actuate circuit breakers in a full bridge which are arranged on a high-voltage side of the DC-DC voltage converter. In addition, the circuit arrangement has at least one comparison unit which is configured to compare a first voltage U dropping across a circuit breaker arranged on a low-voltage side of the DC-DC voltage converter with a first predetermined reference voltage U. In addition, the circuit arrangement has a first measuring unit, configured to start a first time measurement when a pair of the circuit breakers in the full bridge is switched on by the actuating unit and to terminate the first time measurement when U>U.

Abstract: In a method of operating a dual mode DC-DC converter having first and second bridge converters connected via a transformer, a capacitor in series with each winding of the transformer, and an inductance, wherein each bridge converter includes a number of switches operating under the control of a controller, in a first mode of operation, the switching of the number of switches is controlled in a manner to transfer DC electrical power from the first bridge converter to the second bridge converter, or vice versa. In a second mode of operation, one switch of each bridge converter is maintained in a closed state and one switch of each bridge converter is maintained in an open state while the switching of the other of the number of switches of the first and second bridge converters is controlled in a manner to transfer DC electrical power from the first bridge converter to the second bridge converter, or vice versa.

Abstract: Disclosed are a power conversion apparatus and a photovoltaic module. The power conversion apparatus includes a converter unit configured to convert a direct current (DC) voltage from a solar cell module, a clamp unit configured to limit a surge voltage in the converter unit, and a controller configured to control the converter unit. Through this configuration, the power conversion apparatus is capable of limiting a surge voltage depending on operation of the converter unit.

Abstract: Invention is related to a bidirectional switched mode power supply for elevator power systems. The bidirectional switched mode power supply comprises an input for selecting power supply direction of the bidirectional switched mode power supply and a switch having an control pole coupled to the input. The switch is adapted to change the main circuit of the bidirectional switched mode power supply based on the selected power supply direction.