A current limiter for selectively limiting a rate of change of current in a DC electrical network may include a first electrical block including an inductive element and a second electrical block including a bidirectional switch. The first electrical block is connected in parallel with the second electrical block between first and second terminals, and the first and second terminals are connectable to the DC electrical network. The bidirectional switch is switchable to: (1) a first mode to permit current flow through the second electrical block in a first current direction and at the same time inhibit current flow through the second electrical block in a second, opposite current direction; and (2) a second mode to permit current flow through the second electrical block in the second current direction and at the same time inhibit current flow through the second electrical block in the first current direction.

An apparatus for providing protection to an electric circuit includes a P-channel MOSFET; a freewheeling diode coupled to a drain of the P-channel MOSFET and coupled to a load; and a charge pump coupled to a gate of the P-channel MOSEFT. In a normal operating mode, the charge pump receives a voltage from a voltage regulator, and is configured to multiply and reverses the polarity of the voltage to supply to the gate of the MOSFET. In a reverse battery operating mode, the charge pump receives no voltage from the voltage regulator to supply to the gate of the MOSFET causing the MOSFET to deactivate such that when the MOSFET deactivates, current is prevented from flowing through the freewheeling diode to protect the freewheeling diode.

Disconnection of a circulation path through which a circulation current flows is detected while suppressing an increase in circuit scale. A battery monitoring device includes switching circuits that control currents flowing through coils of main contactors by being controlled to be turned on and off, freewheeling diodes that are connected to the coils of the main contactors to form circulation paths for circulating the currents, and a control unit. The control unit measures output voltages of the freewheeling diodes at an input terminal, and detects the disconnection of the circulation paths based on the output voltages of the freewheeling diodes.

A main switch of an electrical system of a vehicle, in particular agricultural machinery, with a first main current path in which a first switch is introduced, and with a second main current path. The main switch comprises a control unit and the first main current path is associated with a first current sensor and the second main current path is associated with a second current sensor. By means of the control unit, the first switch is actuated as a function of a deviation from the electrical currents detected by the two current sensors.

A solid-state magnet control unit includes a housing and magnet controller circuitry mounted within the housing. The magnet controller circuitry controls current passing through a magnet. The magnet controller circuitry includes a power storage unit, drivers in a bridge network, e.g., an insulated gate bipolar transistor (IGBT) in a bridge network, and dump circuitry. The dump circuitry limits circuit damage to the magnet controller circuitry and other components contained within the magnet control unit. When the dump driver is not operational, operation of the magnet control unit is automatically switched to first or second safety mode of operation.

This application provides a converter and an on-board charger, to avoid a short-circuit fault of the converter while inhibiting a surge impact. The converter includes: a power factor correction PFC circuit, a surge protection circuit, and a switch circuit. The PFC circuit is configured to: convert a first component of a first alternating current received by an alternating current terminal of the PFC circuit into a first direct current, and output the first direct current through a direct current terminal of the PFC circuit; and convert a second direct current received by the direct current terminal of the PFC circuit into a second alternating current, and output the second alternating current through the alternating current terminal of the PFC circuit.

A solid-state magnet control unit includes a housing and magnet controller circuitry mounted within the housing. The magnet controller circuitry controls current passing through a magnet. The magnet controller circuitry includes a power storage unit, drivers in a bridge network, e.g., an insulated gate bipolar transistor (IGBT) in a bridge network, and dump circuitry. The dump circuitry limits circuit damage to the magnet controller circuitry and other components contained within the magnet control unit. When the dump driver is not operational, operation of the magnet control unit is automatically switched to first or second safety mode of operation.

Disconnection of a circulation path through which a circulation current flows is detected while suppressing an increase in circuit scale. A battery monitoring device includes switching circuits that control currents flowing through coils of main contactors by being controlled to be turned on and off, freewheeling diodes that are connected to the coils of the main contactors to form circulation paths for circulating the currents, and a control unit. The control unit measures output voltages of the freewheeling diodes at an input terminal, and detects the disconnection of the circulation paths based on the output voltages of the freewheeling diodes.

A generator has a voltage regulator that includes a first control unit for lowering an output voltage of the generator when a first maximum value is exceeded and a second control unit for lowering the output voltage either when a first maximum value is exceeded or when a second maximum value that is different from the first maximum value is exceeded.

A fast shut-off solenoid circuit network includes a solenoid circuit and a current dissipation circuit. The solenoid circuit is operable in response to an electrical current, and configured to operate in an enable mode and a disable mode. The current dissipation circuit is configured to dissipate the current discharged from the solenoid circuit in response to invoking the disable mode. The fast shut-off solenoid circuit network further includes a dissipation bypass circuit. The dissipation bypass circuit is configured to divert the current discharged by the solenoid circuit away from current dissipation circuit when operating in the enable mode.