A system for providing power from an AC power supply to an external load. The system includes a current limiter circuit, connected to an input of a switched-mode power supply. The system includes the switched-mode power supply that provides a first voltage signal and a second voltage signal. The system includes a supervisor circuit that is connected to the first output of the switched-mode power supply and coupled to a relay control circuit. The supervisor circuit monitors the first voltage signal and enables the relay control circuit. The relay control circuit provides a first voltage corresponding to the first voltage signal to a first voltage rail and provides a second voltage corresponding to the second voltage signal to a second voltage rail. A relay powered by a connection to the first voltage rail or the second voltage rail connects the AC power supply to an external load.

Embodiments of the present invention provide a power supply module and a soft start method. The power supply module includes an input detection circuit configured to output a first notification signal to a trigger drive circuit when it is determined that the power supply module receives a power supply signal; the trigger drive circuit configured to, upon receipt of the first notification signal sent from the input detection circuit, wait for a predetermined duration without sending a drive signal to a current limiting circuit, and to send the driver signal to the current limiting circuit when the predetermined duration elapses; and the current limiting circuit configured to limit a current on a Direct Current (DC) bus of the power supply module when the drive signal is not received by the current limiting circuit, and not to limit the current on the DC bus upon receipt of the drive signal.

A circuit breaker with pre-charging and current limiting functions, wherein the circuit breaker is configured for being provided in a power line connecting an electrical energy source and an electric network. The circuit breaker includes a short circuit protection unit including a first semiconductor switch, a precharge unit connected in parallel to the short circuit protection unit and including a second semiconductor switch, and a current limit unit connected in parallel to the short circuit protection unit and to the precharge unit, the current limit unit including a third semiconductor switch.

A switching arrangement for a motor vehicle powered at least partially electrically, including at least one inverter for converting a DC voltage of a high-voltage battery into a multi-phase AC voltage for a travel drive, at least one intermediate circuit capacitor connected to the inverter, and at least one pre-charge resistor, wherein, in a pre-charge mode, the pre-charge resistor serves to prevent current spikes during charging of the at least one intermediate circuit capacitor and, in a heating mode, serves for heating a coolant, wherein electrical current flows through the inverter in both the pre-charge mode as well as in the heating mode.

An electrical system includes a contactor having a pair of contacts and a coil configured to electrically close and open the contacts. The electrical system also includes a high voltage (“HV”) circuit including a power supply electrically connected to at least one of the contacts of the contactor. The electrical system further includes a low voltage (“LV”) circuit electrically connected to the coil and configured to selectively energize the coil of the contactor. A disconnect mechanism is coupled with the LV electrical circuit and operable to electrically open the LV electrical circuit to actuate electrical opening of the contacts of the contactor.

Modular circuit protection devices and configurable panelboard systems include arc-free operation, thermal management features providing safe operation in hazardous environments at lower cost and without requiring conventional explosion-proof enclosures and without entailing series connected separately provided packages such as circuit breaker devices and starter motor contactors and controls.

A power supply device includes a resistor that limits an electric current supplied from an AC power supply, a switching unit that is connected in parallel with the resistor, a rectifier circuit unit that is connected to a subsequent stage of the resistor and the switching unit and rectifies an AC voltage of the AC power supply, a booster circuit unit, a DC-voltage detection unit that detects a DC voltage output from the booster circuit unit, an AC voltage detection unit, a protection setting unit that compares a first protection voltage calculated on the basis of the boosting level by the booster circuit unit with a second protection voltage calculated based on the AC voltage detected by the AC-voltage detection unit and sets either one as a protection voltage, and a control unit that opens the switching unit when the DC voltage falls below the protection voltage and stops boosting.

Features are disclosed for charging a battery using a power supply in series with a diode. A power supply can be connected in series with a diode to restrict an inrush current resulting from connection of the power supply with a battery. In some embodiments, the power supply can further include a plurality of power supplies to restrict the amount of inrush current a single power supply can provide. In other embodiments, the power supply can also include a bypass capacitor that the power supply charges before supplying current to the battery. The power supply can regulate the amount of current that is applied to the battery and prevent inrush current from damaging the battery. Multiple power supplies add to overall reliability.

A detection circuit includes a first transistor coupled to a gate of a high power transistor, a second transistor whose source is coupled to a drain of the first transistor, a first voltage divider coupled to a source of the first transistor, and a second voltage divider coupled to the source of the second transistor. The first transistor is configured to generate a first transistor output voltage representative of a gate voltage of the high power transistor shifted based on a first gate-to-source voltage of the first transistor. The second transistor is configured to generate a second gate-to-source voltage substantially equal to the first gate-to-source voltage. The first divider is configured to divide the first transistor output voltage by a first factor. The second divider is configured to divide the second gate-to-source voltage by a second factor correlated with the first factor.

An electric power receiving apparatus of an electric power transmitting system includes an overvoltage suppressing unit connected in parallel to a resonant circuit. The overvoltage suppressing unit is formed by an impedance element. Impedance of the impedance element is set to such a value that a rise in a voltage across at least one pair of electric power receiving electrodes is suppressed as compared to a case in which the impedance element is not connected, in the process in which coupling capacitance Cm between electric power transmitting electrodes and the electric power receiving electrodes changes from a value held while the electric power transmitting electrodes and the electric power receiving electrodes are in a predetermined positional relationship during normal electric power transmission to substantially zero.