A battery protection circuit protects a rechargeable battery from overdischarge, by turning off a transistor inserted in series in a current path between a negative electrode of the battery and a negative terminal coupled to ground of a load or a charger. A detection circuit detects a power source voltage between power source and ground terminals, and a control circuit pulls down a monitor terminal potential to a ground terminal potential by turning off the transistor and stopping battery discharge when the power source voltage lower than an overdischarge detection voltage is detected. The control circuit cancels pull-down of the monitor terminal potential to the ground terminal potential when the power source voltage higher than an overdischarge reset voltage is not detected until a predetermined time elapses in a state in which the battery discharge is stopped and the monitor terminal potential is pulled down to the ground terminal potential.

A regulating device includes a common mode choke, a switch device and a first control unit. The common mode choke includes an input side and an output side, wherein the input side is coupled to a power-supply device. The switch device includes a first input node, a second input node, a first output node, a second output node, and a third output node. The first output node is coupled to a first battery set, and the second output node is coupled to a second battery set, and the third output node is an empty node. The first control unit compares the first terminal voltage to the second terminal voltage for controlling the first input node to selectively connect to the first output node or the second output node and controlling the second input node to selectively connect to the second output node or the third output node.

A monitoring device includes a first monitoring section that monitors voltages of the plurality of battery cells connected in series and a first wiring section electrically connects the monitoring section and a plurality of battery cells. A first electrode terminal group and a second electrode terminal group in which a plurality of positive terminals and a plurality of negative terminals are aligned and alternate in a longitudinal direction are aligned in a horizontal direction by aligning the plurality of battery cells in the longitudinal direction. The first wiring section is provided with a front wiring section and a back wiring section having a both-end wiring pattern electrically connected to electrode terminals of two battery cells positioned at both ends of the plurality of battery cells aligned in the longitudinal direction and an even-number wiring pattern connected to electrode terminals of even-numbered battery cells in an aligning order.

A vehicle includes a low-voltage battery, a high-voltage battery, and a converter that decreases voltage provided from the high-voltage battery to the low-voltage battery. A system controller of the vehicle is programmed to use the converter, in a key-off cycle, to charge the low-voltage battery a calibrated number of times that the low-voltage battery drops below a predefined state-of-charge threshold, and send a wireless notification a subsequent time the low-voltage battery drops below the threshold. A notification is sent to a predefined contact address when a periodically computed state of charge of a low-voltage battery of a vehicle falls below a predefined threshold. Using a converter, voltage provided from a high-voltage battery of the vehicle to the low-voltage battery is decreased to charge the low-voltage battery responsive to receipt from the contact address of a response indicating approval of the charge.

The capacitor quick-charge apparatus includes an input AC power source, a phase modulator, a rectifier, a shunt, a module current supply, a current control element, a capacitor, a resistance, a comparator, a variable resistor, an Operational Amplifier 1 (OP AMP 1) to an Operational Amplifier 5 (OP AMP 5), an Auto Voltage Regulator (AVR) or a Micro Control Unit (MCU), and a monitor system.

There are provided a charge/discharge control circuit which is equipped with a differential amplifier configured to detect charging currents of a plurality of secondary batteries connected in parallel, and a charge control circuit configured to output an output signal of the differential amplifier to charge control terminals according to a reception of a control signal to permit the charging of each of the secondary batteries, and which is capable of charging the secondary batteries connected in parallel with uniform charging currents, and a battery apparatus equipped with the charge/discharge control circuit.

Systems and methods provide intelligent battery charging and balancing. Energy deficits can be forecasted based on historical data and forecasted energy generation. The deficits can be used to determine charging currents over a period of time, and battery cassettes can be charged according to the charging currents to compensate for the forecasted energy deficit. The states of charge of the battery cassettes can be periodically rebalanced. The battery cassettes can be coupled in series and charged and balanced while providing output to a load.

The present disclosure provides a device to be charged and a charging method. The device to be charged includes: a charging interface; a first charging circuit, coupled with the charging interface, configured to receive an output voltage and an output current of an adapter via the charging interface and to directly apply the output voltage and the output current of the adapter to both ends of a plurality of battery cells coupled in series in the device to be charged, so as to perform a direct charging on the plurality of battery cells. With the present disclosure, heat generated in the charging process can be reduced while ensuring the charging speed.

A charging apparatus includes: an electric power source circuit including a first inverter and a second inverter to drive one motor; and a charging port having a positive electrode terminal connected to a positive electrode side of a first storage battery, and a negative electrode terminal connected to a negative electrode side of a second storage battery. In the case where the battery charger outputs first electric power, the first storage battery and the second storage battery are connected in parallel when being charged with the first electric power. In the case where the battery charger outputs second electric power that is larger than the first electric power, the first storage battery and the second storage battery are connected in series when being charged with the second electric power.

A system and apparatus for autonomous charge balancing of an energy storage device of the microgrid. In one embodiment the apparatus comprises a power conditioner, coupled to the energy storage device, comprising a droop control module for operating the power conditioner, during an autonomous mode of operation, such that the state of charge of the energy storage device is autonomously driven toward the state of charge of at least one other energy storage device of the microgrid.