Abstract: A control method, which is applied to a conversion circuit including at least one bridge arm and an inductor, the bridge arm including an upper semiconductor switch and a lower semiconductor switch connected in series, and one end of the inductor being connected to a midpoint of the bridge arm, includes: judging a direction of current of the inductor when a scram event occurs in the conversion circuit; turning on the upper semiconductor switch and turning off the lower semiconductor switch when the direction of current of the inductor is judged as a first direction, wherein the first direction is a forward conduction direction of the lower semiconductor switch; and turning off the upper semiconductor switch and turning on the lower semiconductor switch when the direction of current of the inductor is judged as a second direction.

Abstract: The present disclosure discloses a current detecting circuit of a power converter, which includes a transformer including: a magnetic core, a primary winding and a secondary winding, the primary winding and the secondary winding being coupled through the magnetic core, and a combination of the primary winding, the secondary winding and the magnetic core being used to transmit a main power of the power converter, the current detecting circuit includes: an auxiliary winding coupled to the secondary winding, the auxiliary winding and the secondary winding having the same number of turns and their dotted terminals being connected; and an impeder, one end thereof being coupled to the auxiliary winding to form a series branch, which is coupled in parallel to the secondary winding, and a terminal voltage of the impeder after being filtered being proportional to a magnitude of an output current of the power converter.

Abstract: A network management system and method for automatic registration of network device thereof are disclosed. The system has an electronic device, a network device and a control host. The electronic device generates and sends configuration data to the network device according to a user operation. The network device automatically generates registration data having device identity data and location identity data, connects to a communication network according to the configuration data, and sends the registration data to the control host via the communication network. The control host determines classification information according to the registration data and configures the device identity data to correspond to the classification information and location identity data for completing registration of the network device. The present disclosed example can effectively omit a registration operation inputted by the user manually via configuring the network device to register at the control host automatically.

Abstract: A power circuit includes a voltage converter, an UVLO circuit, a power transistor, and a driving circuit. The voltage converter converts an external voltage to a supply voltage according to an UVLO signal. The UVLO circuit generates the UVLO signal when the external voltage exceeds a threshold. The power transistor draws a power current according to a voltage of a driving node. The driving circuit includes a high-side transistor, a low-side transistor, a charge pump, and a pre-driver. The high-side transistor provides the supply voltage to the driving node according to a high-side voltage of a high-side node. The low-side transistor couples the driving node to a ground according to a first internal signal. The charge pump generates a high-side voltage that exceeds the supply voltage according to the first internal signal. The pre-driver generates the first internal signal according to a control signal.

Abstract: The present disclosure provides a multi-mode dimming control method and a dimming circuit. The multi-mode current control method includes: receiving a dimming signal, and controlling the dimming circuit to be operated in a plurality of modes in an arbitrary order according to the dimming signal, wherein the plurality of modes include any two or all of a first dimming mode, a second dimming mode, and a third dimming mode. Also, the dimming circuit can be operated in different combinations of different modes according to actual needs, so that the requirements of a wide dimming range and a low output current ripple can be realized.

Abstract: A flyback converter includes: a transformer, including a primary winding and a secondary winding; a primary side switch electrically coupled to the primary winding; a feedback circuit, configured to detect an output voltage of a load and output a feedback voltage signal; a current detecting circuit, configured to sample current flowing through the primary side switch and output a current signal; and a control circuit, coupled to the feedback circuit and the current detecting circuit and configured to respectively receive the feedback voltage signal and the current signal, and output a switch control signal to the primary side switch; and wherein the control circuit configured to control a switching frequency of the primary side switch to increase with increase of an output power, and an increasing speed of the switching frequency to decrease with the increase of the output power.

Abstract: The present disclosure provides a magnetic component including a winding, a first magnetic core and a circuit component, and a wireless power-transferring device including the magnetic component. The winding is formed by winding a coil, and having a first penetration portion at a middle portion of the winding. The first magnetic core is disposed at a side of the winding, and a first insulating support portion is disposed between the first magnetic core and the winding. The circuit component is located within the first penetration portion and electrically connected with the winding. Disposing the circuit component within the first penetration portion at the middle portion of the winding can effectively save space.

Abstract: The present disclosure provides a wireless power transmitting module and an installation method thereof, wherein the wireless power transmitting module comprises: an insulating bracket, a first side of which has a first central space; a coil, disposed around the first central space; and a circuit component, at least a part of which is located in the first central space, electrically connected to the coil. The present disclosure makes full use of the central blank space of the coil, and places the circuit component at the center of the coil, thereby realizing a miniaturized structure, improving space utilization and greatly reducing volume.

Abstract: A method for measuring sensorless brushless-DC motor load, adapted to a home appliance, including: accelerating, through the use of a driving circuit, a BLDC motor from an initial rotational speed to a first rotational speed; disabling, through the use of a control circuit, the driving circuit; obtaining, through the use of a detecting circuit, phase voltage information corresponding to each phase of the BLDC motor when the BLDC motor is decelerated from the first rotational speed to a second rotational speed; obtaining, through the use of the control circuit, a first time period during which the BLDC motor decelerates from the first rotational speed to the second rotational speed according to at least one piece of the phase voltage information; obtaining, through the use of the control circuit, a first predicted weight of a load according to the first time period and a first lookup table.

Abstract: An insulated housing, in a cylindrical structure, includes an inner metal layer, an insulating layer and an outer metal coating. The insulating layer is positioned between the inner metal layer and the outer metal coating. In any end of the cylindrical structure, both a distance from the end of the inner metal layer to the end of the cylindrical structure and a distance from the end of the outer metal coating to the end of the cylindrical structure are not equal to zero, and the distance from the end of the inner metal layer to the end of the cylindrical structure is larger than the distance from an end of the outer metal coating to the end of the cylindrical structure. The inner metal layer is composed of one first metal cylinder and two second metal cylinders respectively disposed on the both ends of the first metal cylinder.

Abstract: An inverter box structure includes an inverter accommodating box of an inverter circuit and a junction box. A first quick connector, disposed on the inverter accommodating box, includes a first connection end and a second connection end. The first connection end of the first quick connector is electrically with the inverter circuit. A second quick connector, disposed on the junction box or in the junction box, includes a third connection end and a fourth connection end. The third connection end of the second quick connector is connected to an inner wire of the junction box. A casing of the inverter accommodating box equipped with the first quick connector is opposite to a casing of the junction box equipped with the second quick connector, and the second connection end of the first quick connector matches with and is electrically connected to the fourth connection end of the second quick connector.

Abstract: A mobile high voltage generating device for providing power to an X-ray apparatus, includes a power supply unit including a battery and an isolated DC-DC converter electrically coupled with the battery; an energy storage unit, electrically coupled to the isolated DC-DC converter of the power supply d a voltage conversion unit coupled between the energy storage unit and a radiation source of the X-ray apparatus; wherein the isolated DC-DC converter includes: a first inverter circuit coupled to a battery, a first rectifier circuit coupled to the energy storage unit, a first transformer including a primary winding and a secondary winding. The primary winding is coupled to the first inverter circuit and the secondary winding is coupled to the first rectifier circuit.

Abstract: The present disclosure relates to a method and apparatus for charging and discharging. The apparatus includes: an AC power terminal, including first to third nodes, and a first center line node, and being configured to receive input an AC input or send an AC output; a power conversion stage, including fourth to sixth nodes, and a second center line node; a first bus capacitor and a second bus capacitor both coupled to the second center line node, the first center line node being coupled to the second center line node; a first switch set; a second switch set; a control module, coupled to the first switch set, the second switch set, the AC power terminal, and the power conversion stage.

Abstract: A drive circuit of a power semiconductor switch includes: a pulse modulation circuit having a first terminal configured to receive a fault signal, an isolation transformer, and a pulse demodulation circuit; when there is no fault signal being received, the pulse modulation circuit outputs a first turn on pulse signal and a first turn off pulse signal via the isolation transformer and the pulse demodulation circuit to charge/discharge a gate capacitor of the power semiconductor switch, so as to drive the power semiconductor switch to be turned on and turned off at a first speed; when the fault signal is received, the pulse modulation circuit outputs a second turn off pulse signal via the isolation transformer and the pulse demodulation circuit to discharge the gate capacitor of the power semiconductor switch, so as to drive the power semiconductor switch to be turned off at a second speed.

Abstract: The present disclosure relates to the technical field of power electronics, and provides a power supply system, including: a high-voltage input power distribution cabinet, a high-low voltage conversion cabinet, and a low-voltage output and control cabinet, wherein the high-low voltage conversion cabinet is provided with at least one high-voltage chamber and at least one low-voltage chamber, the high-low voltage conversion cabinet is further provided with an insulating partition between the high-voltage chamber and the low-voltage chamber, the low-voltage chamber is provided with a low-voltage bus bar, and the high-voltage chamber is provided with a high-voltage bus bar; the high-low voltage conversion cabinet is further provided with a plurality of power supply modules, and each of the power supply modules bridges the high-voltage chamber and the low-voltage chamber, the power supply module includes a high-voltage cavity, a low-voltage cavity and an isolation unit.

Abstract: A direct current power supply system includes at least one first input source, a second input source, a phase shifting transformer set, a rectifier set and a monitoring module. The phase shifting transformer set is for converting a medium voltage alternating current of the first input source and/or the second input source to a low voltage alternating current. The rectifier set is for rectifying the low voltage AC to a low voltage DC. The phase shifting transformer set and the rectifier set are disposed either in a power supply housing, or in two adjacent power supply housings. The monitoring module includes a phase shifting transformer monitoring unit for retrieving at least one of temperature data, voltage data and current data of the phase shifting transformer set and a rectifier monitoring unit for retrieving at least one of temperature data, voltage data and current data of the rectifier set.

Abstract: A plug device for plugging in at least two optical modules is provided, wherein the plug device is disposed in a housing and includes a first circuit board, a first connecting module, and a movable module. The first connecting module includes a plurality of electrical connectors, and the movable module includes a plate, at least one frame, and at least one joining member. The electrical connectors are disposed on the first circuit board. The frame is connected to the plate and has a plurality of accommodating portions. The optical modules can be respectively accommodated in the accommodating portions. The plate can be affixed to or separated from the housing by the joining member.

Abstract: The present disclosure relates to a DC converter, a DC converter group and a method of connecting the DC converter group. The DC converter includes a DC conversion circuit converting a DC input voltage into a DC output voltage, and a filter module electrically coupled to an input end and an output end of the DC conversion circuit. The filter module includes an input inductor component electrically coupled to the input end of the DC conversion circuit, and an output inductor component electrically coupled to the output end of the DC conversion circuit, wherein the input inductor component and the output inductor component share the same magnetic core.

Abstract: A method of charging a battery and a system using the same are provided. The method includes: detecting a terminal voltage of a battery; When the terminal voltage is less than a voltage threshold, performing quick charging which includes: calculating a rising rate of the terminal voltage, comparing the rising rate with a rising rate reference value, and controlling the terminal voltage according to the comparison result; and when the terminal voltage is not less than the voltage threshold, performing low current floating charging which includes: intermittently charging the battery by a predetermined floating charging period, calculating a falling rate of the terminal voltage, comparing the falling rate with a falling rate reference value, controlling the terminal voltage according to the comparison result, in a first time duration of the floating charging period, and suspending charging in a second time duration of the floating charging period.

Abstract: The present disclosure provides a gate circuit and a gate drive circuit for a power semiconductor switch, including: a zener diode and a charge dissipation circuit. A first end of the zener diode is connected to a first end of the charge dissipation circuit and a gate of the power semiconductor switch, a second end of the zener diode is connected to a second end of the charge dissipation circuit and a second end of the power semiconductor switch. A first parasitic capacitor is formed between a first end and the gate of the power semiconductor switch, and a second parasitic capacitor is formed between the gate and the second end of the power semiconductor switch.