A charging device basically includes a first power source, first and second device-side connection terminals, a first resistance, a detection unit and a device-side controller. The first resistance is connected between the first power source and the first device-side connection terminal. The detection unit detects an inter-terminal voltage between the first device-side connection terminal and the second device-side connection terminal. A vehicle-side controller is connected between a first vehicle-side connection terminal connected to the first device-side connection terminal and a second vehicle-side connection terminal connected to the second device-side connection terminal. The device-side controller determines that the charging-device-side charging connector and the vehicle-side charging connector are turned into a non-connected state from a connected state by a fact that the inter-terminal voltage detected by the detection unit becomes greater than a predetermined voltage.

A battery management system of a battery apparatus includes a circuit to which a voltage from a power supply is supplied and configured to be used to manage the battery pack. A processor of the battery management system controls the circuit, measure a voltage supplied from the power supply, and corrects the measured voltage based on a voltage drop occurred in the circuit.

A discharge circuit for an X capacitor has a first voltage detection circuit providing a first indicating signal based on a voltage across two input terminals of a switching converter to indicate whether the two input terminals are connected to an AC power source, and a discharge module starting a discharge operation on the X capacitor based on first indicating signal, and the discharge operation discharges the X capacitor during a first time period, and stops discharging the X capacitor and compares a sampled signal with the voltage across the two input terminals during a following second time period.

A system for supplying electrical energy to an energy-absorber mobile device having two electrically conductive secondary terminals includes a power-source base with electrically conductive primary terminals configured to be arranged in contact with the two secondary terminals when the mobile device is positioned on the base; a supply and control subsystem having a line selector whose outputs are connected to the primary terminals, a rectifier and programmable power supply providing energy, and a mini-processor connected to the line selector and to the rectifier and programmable power supply. The line selector has two input lines, between which a voltage difference higher than zero is applied and which is configured to apply the voltage difference cyclically to all possible pairs of output lines based on the commands received from the mini-processor.

An energy management system (401) for a kitchen appliance (201), the energy management system (401) comprising: a mains power system, a backup energy storage system (405), and a con-troller (411), wherein the controller (411) is arranged to: determine a state of health of the energy storage system; determine a state of charge of the energy storage system; determine how energy from the energy storage system is to be used based on the determined state of health, the determined state of charge and at least one measured variable obtained from a kitchen appliance (201), and apply the energy to operate at least one function of the kitchen appliance (201).

Provided is an electronic electricity meter. Since inductive power from a magnetic field surrounding a transmission line is generated using a current transformer, and the inductive power is stored to be used as a driving power source for the electricity meter, the present invention can prevent power from being consumed by the electricity meter in an unloaded state. In addition, the present invention can protect the electricity meter from a surge voltage, lightening, or the like by insulating the transmission line and internal components from each other. In addition, when a power cut-off instruction is received from the electrical energy measurement server, the present invention can cut off power supply to a load by turning off a switch in a power source cut-off unit installed on the transmission line, and when a power supply instruction is received from the server, can remotely control power supply to the load.

A mobile device includes; a power line communication ( ) module that communicates data with an external device via a power line, receives a first preamble signal from the external device during a first preamble interval, receives a voltage signal as the data during a data reception interval following the first preamble interval, and demodulates the voltage signal to provide a demodulated voltage signal, a frequency/duty detector that detects a frequency and a duty of the first preamble signal, and a control circuit that performs signal a data determination operation on a demodulated voltage signal during a data period and using the first detected frequency and the first detected duty.

Operating electric power is preferably supplied to a battery assembly control circuit from both a power converting device and a battery module. An electricity storage device includes a battery module including battery cells and a battery assembly control circuit, and a power converting device configured to charge the battery module with a commercial power supply and to supply electric power to a load. The power converting device supplies electric power to the battery assembly control circuit while an output voltage of the power converting device is higher than a predetermined voltage. The battery module starts to supply operating electric power to the battery assembly control circuit upon detecting that the electric power from the power converting device starts to be supplied to the battery assembly control circuit. The battery module stops supplying the electric power to the battery assembly control circuit when the battery module stops being discharged.

The present invention discloses a switch on/off circuit for a battery management system, including a driving signal input terminal, a start-up driving signal output terminal, a power supply terminal, a power signal extraction circuit, a trigger circuit, and a switch. The driving signal input terminal is connected to the start-up driving signal output terminal by the switch. The power signal extraction circuit is connected to the power supply terminal, and is configured to output a control signal based on a power signal inputted from the power supply terminal. The trigger circuit is electrically connected to the power signal extraction circuit. The trigger circuit is configured to control the switch on or off according to a transition of the control signal. The switch on/off circuit for a battery management system provided in the present invention, by using the trigger circuit to receive the switch on/off signal outputted by the power signal extraction circuit, realizes the unified management of switch on and off signals. The switch on/off circuit is easy to expand and has high reusability.

Discussed is a battery system including a battery; a first main relay connected between one electrode and a first output terminal of the battery; a pre-charge relay connected to the first main relay in parallel; a second main relay connected between another electrode and a second output terminal of the battery; and a battery management system controlling charging and discharging of the battery, and controlling the first main relay, the pre-charge relay, and the second main relay, wherein the battery management system opens the first main relay, the pre-charge relay, and the second main relay when a received power voltage is a predetermined reference voltage or less, closes the pre-charge relay and the second main relay to execute a pre-charge when the power voltage is higher than the reference voltage, and closes the first main relay after the pre-charge is completed.