Abstract: The disclosure discloses a packaging module of a power converting circuit and a method for manufacturing the same. The packaging module of the power converting circuit includes a substrate, a molding layer and a plurality of pins. A power device is assembled at the substrate, a plurality of pins electrically are coupled to the power device, the molding layer covers the surface of the substrate with the power device, and at least a contact surface of the pins configured to electrically connect an external circuit is exposed. The molding layer includes a main hat-body part and a hat-brim part, the main hat-body part and the hat-brim part form a hat-shaped molding layer, and the hat-brim part is used to increase a creepage distance between the contact surfaces of the pins located at the top of the molding layer and the bottom of the substrate.

Abstract: A light source system includes a laser module and at least one light coupling module. The laser module includes a plurality of laser sources, each of which provides a light beam. The light coupling module has a light incident surface, a plurality of total reflection surfaces and a light output surface. The light incident surface includes a plurality of light incident zones, and the light incident zones are disposed corresponding to the laser sources, respectively. The total reflection surfaces are disposed corresponding to the light incident zones, respectively. The projected areas of the total reflection surfaces on the light output surface have no overlap with each other.

Abstract: A five-level converting device includes a first switch module, a second switch module and a third switch modules each connects to a neutral point, a positive terminal and a negative terminal of a bus capacitor module. A first switch module includes a plurality of bidirectional switching circuits cascaded to each other, and each bidirectional switching circuit includes two first switching units reversely connected in series. Second switch module includes a plurality of second switching units connected in series. Third switch module includes a plurality of third switching units connected in series. A first flying capacitor unit is connected across the first switching module and a second switch module, and a second flying capacitor unit is connected across the first switching module and a third switching module. The first flying capacitor unit and the second flying capacitor unit are connected to different connection points between the first switch units respectively.

Abstract: A method for assembling a power conversion device is provided. The method includes mounting an electronic component on a heat-dissipating base, and electrically connecting a printed wiring board with the electronic component mounted on the heat-dissipating base.

Abstract: An integrated magnetic component includes a magnetic core and a plurality of windings. The magnetic core includes at least four magnetic columns. The windings include a primary winding, a first secondary winding, a second secondary winding, and an inductor winding. The primary winding, the first secondary winding and the second secondary winding are wound on one of the magnetic columns. The inductor winding is wound on another magnetic column, and the inductor winding is coupled to the connection where the first secondary winding and the second secondary winding couple to each other. By integrating a transformer and a filter inductor into the integrated magnetic component, the number of the magnetic components, the overall volume, and the weight may be reduced while the mechanical properties may be promoted and the loss of the component connections may be reduced.

Abstract: A power adaptor includes an adaptor body, an output connector, and a replaceable tip. The output connector is connected to the adaptor body. The replaceable tip is detachably connected to the output connector. The replaceable tip includes four terminals, a first conductive element, and a second conductive element. The first conductive element is connected to two or three of the terminals. The second conductive element is connected to at least one of the remaining terminals. The adaptor body outputs an output voltage depending on the replaceable tip.

Abstract: A converter module includes: a system board; and an isolated rectifier unit connected with the system board via at least one pin, the isolated rectifier unit including: a magnetic core including at least one core column parallel to the system board and two cover plates provided at both ends of the core column; and multiple carrier board units provided between the two cover plates and perpendicular to the system board, wherein the carrier board unit includes at least one via hole, at least one primary winding and at least one secondary winding; and wherein the at least one core column passes through the via hole of the carrier board unit, the pin is provided at one side of at least one of the carrier board units close to the system board and configured to connect the carrier board units with the system board.

Abstract: An electronic device includes a heat-dissipating base, a first printed wiring board assembly, and a second printed wiring board assembly. The first printed wiring board assembly is disposed on the heat-dissipating base. The first printed wiring board assembly includes a first printed wiring board and at least one first electronic component. The first electronic component is disposed on the first printed wiring board, such that the first printed wiring board assembly has a raised portion and a concave portion relative to the raised portion. The second printed wiring board assembly is at least partially disposed in the concave portion.

Abstract: A method for detecting failure of soft start includes: connecting a variable frequency device to a load; detecting an energy storage unit at a first voltage level; generating an output current to the load; detecting the energy storage unit changed from the first voltage level into a second voltage level; generating a reference voltage value according to the output current and determining whether a voltage difference value between the first voltage level and the second voltage level is larger than the reference voltage value; determining whether a voltage peak-to-peak value of the energy storage unit is smaller than a set value by the controller if the voltage difference value is larger than the reference voltage value; and controlling the inverter circuit to stop outputting the output current to the load if the voltage peak-to-peak value is smaller than the set value.

Abstract: A power integrated module, including at least one first bridge formed in a chip, wherein the first bridge includes: a first upper bridge switch, formed by a plurality of first sub switches formed in the chip connected in parallel, and including a first, a second and a control end; a first lower bridge switch, formed by a plurality of second sub switches formed in the chip connected in parallel, and including a first, a second and a control end; a first electrode, connected to the first end of the first upper bridge switch; a second electrode, connected to the second end of the first lower bridge switch; and a third electrode, connected to the second end of the first upper bridge switch and the first end of the first lower bridge switch, wherein the first, the second and the third electrode are bar-type electrodes arranged side by side.

Abstract: A dimmable instant-start ballast for a plurality of LED lamps and/or a plurality of fluorescent lamps is provided, which includes an isolated dimming interface, a duty control device, a dimming switch, and an inverter circuit. The isolated dimming interface receives a dimming signal to generate a dimming voltage. The duty control device generates an operation signal according to the dimming voltage. The dimming switch periodically couples a first node to a ground according to the operation signal. The inverter circuit receives a rectified voltage and is coupled to the first node. When the first node is coupled to the ground terminal, the inverter circuit provides a lamp current for the LED lamps and/or the fluorescent lamps.

Abstract: The centrifugal channel device includes a channel body, a collecting unit and a waste liquid tank. The channel body includes a first surface and a second surface relatively disposed. The channel body includes a sample inlet, a sample channel, an isolation tank, a reagent inlet, a reagent channel and a mixing channel. The sample inlet is disposed on the first surface. The sample channel is connected to the sample inlet. The isolation tank is adjacently disposed and communicates with the sample channel. The reagent inlet is disposed on the first surface. The reagent channel is connected to the reagent inlet. One end of the mixing channel is connected with the sample channel and the reagent channel. The collecting unit has an opening and an overflow hole. The opening communicates with another end of the mixing channel. The waste liquid tank communicates with the opening of the collecting unit.

Abstract: A power supply device includes a power supply module, a high voltage conversion module and a control module. The high voltage conversion module includes a first high-voltage output module and a second high-voltage output module both connected to the power supply module. The control module is connected to the first high-voltage output module and the second high-voltage output module to respectively sample a first output voltage of the first high-voltage output module and a second output voltage of the second high-voltage output module and generate a power control signal, a first control signal and a second control signal respectively used to control the power supply module, the first high-voltage output module and the second high-voltage output module. There is a phase difference between the first control signal and the second control signal to interleaving control the first high-voltage output module and the second high-voltage output module.

Abstract: A diode device including a III-N compound layer is provided. The III-N compound layer has a channel region therein. A cathode region is located on the III-N compound layer. A first anode region is located on the III-N compound layer and extends into the III-N compound layer. The bottom of the first anode region is under the channel region. A second anode region is located on the III-N compound layer between the cathode region and the first anode region, and extends into the III-N compound material layer. The second anode region includes a high-energy barrier region. The high-energy barrier region adjoins a sidewall of the first anode region. A method for manufacturing a diode device is also provided.

Abstract: The present application discloses a device for wireless charging circuit, comprising: a primary circuit box, which comprises at least one first switch unit; a secondary circuit box, which comprises at least one second switch unit; a transmission plate, which comprises a primary inductor of a transformer and a primary compensation capacitor, the primary inductor being coupled in series with the primary compensation capacitor; a receiving plate, which comprises a secondary inductor of the transformer; the transmission plate and the receiving plate are magnetically coupled with each other; the transmission plate is coupled with the primary circuit box; and the receiving plate is coupled with the secondary circuit box. The voltage between external terminals of transmission plate and the voltage between external terminals of receiving plate can satisfy the safety requirement.

Abstract: A magnetic structure includes at least one bobbin and a core. Each of the bobbin has at least one winding portion in which a through passage is provided along its longitudinal direction, the core has at least one column, the column is received in the through passage so that a heat dissipation space is formed between an outer wall of the column and an inner wall of the through passage. In the magnetic structure according to the present disclosure, during the operation of the magnetic structure, the heat generated from the column and from an inner layer of a coil wound on the winding portion both can be quickly dissipated through the heat dissipation space, and thus the heat dissipation efficiency of the magnetic structure according to the present disclosure is improved.

Abstract: A ventilation device includes a passage unit (100), a wind turbine (200) and a fan (300). The wind turbine (200) is provided above the passage unit (100), and the fan (300) is provided within the wind turbine (200). The rotation of the wind turbine (200) drives the fan (300) to rotate, so that the air within the passage (100) is exhausted by the fan.

Abstract: A screen is disclosed. The screen includes an angle magnifying unit and a deflecting unit. The angle magnifying unit has a first lens assembly and a second lens assembly. The first and second lens assemblies are aligned along a first direction. The first lens assembly has a plurality of first lenses, and each of the first lenses has a first radius of curvature. The second lens assembly has a plurality of second lenses, and each of the second lenses has a second radius of curvature. The magnification of the angle enlarging unit is the ratio of the first radius of curvature to the second radius of curvature. Furthermore, the deflecting unit is disposed between the first lens assembly and the second lens assembly. The deflecting unit has a plurality of deflecting prisms that aligned along a second direction. The second direction is perpendicular to the first direction.

Abstract: A method for controlling converter such as a Flyback converter is disclosed. A load of the Flyback converter varies between zero and a peak value. The method includes: a load detecting step for detecting the load; and an operating mode control step for controlling the Flyback converter to switch between two or more of a continuous conduction mode, a valley conduction mode and a burst mode according to the load. A converter such as a Flyback converter is also provided.

Abstract: A power module includes: a base plane; at least one switch chip assembled on the base plane; and a voltage clamping circuit for clamping a voltage spike occurring on the at least one switch chip, comprising components of a charging loop, wherein the components of the charging loop at least comprise a capacitor, wherein a projection of a center point of at least one of the components of the charging loop on the base plane is located within at least one first circle, defined with a center of the first circle being a center point of the at least one switch chip, and with a radius of the first circle being a product of a maximum one of a length and a width of the at least one switch chip and a first coefficient, which is a multiple of 0.5.