The disclosure relates to a method for the battery management of a battery which comprises a plurality of battery cells and which is fitted with a battery management system for monitoring battery functionality and with a charge state compensation system, wherein the battery management system comprises a plurality of sensor control devices and a main control device, said control devices being connected with one another via a communication channel, and wherein the charge state compensation system has a number of charge state compensation resistors being put into operation via the sensor control devices for a charge state compensation of battery cells. The sensor control devices save information about performed charge state compensations in non-volatile memory. A computer program, a battery management system, a battery system and a motor vehicle, which are designed to carry out the method, are also described.

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.

The systems and methods described herein are directed to techniques for improving battery life performance of end devices in resource monitoring systems which transmit data using low-power, wide area network (LPWAN) technologies. Further, the techniques include providing sensor interfaces in the end devices configured to communicate with multiple types of metrology sensors. Additionally, the systems and methods include techniques for reducing the size of a concentrator of a gateway device which receives resource measurement data from end devices. The reduced size of the concentrator results in smaller, more compact gateway devices that consume less energy and reduce heat dissipation experienced in gateway devices. The concentrator may comply with modular interface standards, and include two radios configured for transmitting 1-watt signals. Lastly, the systems and methods include techniques for fully redundant radio architecture within a gateway device, allowing for maximum range and minimizing downtime due to transmission overlap.

An electric storage apparatus according to one aspect of an embodiment includes a plurality of storage batteries, a virtual processing unit, and a connection controlling unit. The virtual processing unit virtually and sequentially connects in parallel two or more storage batteries, of the plurality of storage batteries, having a potential difference or potential differences within a predetermined range so as to equalize electric potentials of the two or more storage batteries. The connection controlling unit connects in parallel the two or more storage batteries in a connection order for maximizing the number of the two or more storage batteries to be connected in parallel when the virtual processing unit sequentially connects in parallel the two or more storage batteries in an order from highest electric potential to lowest one and in an order from lowest electric potential to highest one.

A battery thermal event detection system includes a battery, a chemiresistor, and a temperature-sensitive sample in contact with a surface of the battery. The sample is configured to, responsive to a change in battery temperature, release a gas configured to alter a resistance of the chemiresistor. The system further includes a controller coupled with the chemiresistor and configured to, responsive to detecting a change in the resistance greater than a threshold change, reduce power supplied by the battery.

Provided is an electric device that incorporates a first rechargeable battery (11) and a second rechargeable battery (12) that is lower, in a full charge voltage, than the first rechargeable battery (11). The electric device includes: a first power source circuit (19) that steps down a voltage output by the first rechargeable battery (11) to a first voltage and outputs the first voltage; and a second power source circuit (20) that steps down a voltage output by the second rechargeable battery (12) to a second voltage that is lower than the first voltage and outputs the second voltage.

A method for controlling earphone switching and an earphone are provided. The method includes the following. A first earphone acquires a first remaining power and a first operating parameter of the first earphone and a second remaining power and a second operating parameter of a second earphone. The second earphone serves as a slave earphone. The first earphone predicts a first battery life of the first earphone according to the first remaining power and the first operating parameter and a second battery life of the second earphone according to the second remaining power and the second operating parameter. The first earphone predicts switches the second earphone to serve as a master earphone and the first earphone to serve as a slave earphone, when a difference between the second battery life and the first battery life is greater than a first preset threshold.

The present application provides an electric energy allocation bus system, including one or more pairs of electric energy allocation buses, which realizes controllable electric quantity transfer among batteries, power generation devices and electrical loads. The electric energy allocation bus system has an electric energy transfer mode between the batteries and the power generation devices called valley filling mode; an electric energy transfer between the batteries and the electric loads called peak clipping mode; and an electric energy transfer between the power generation devices and the electric loads called direct power supply mode. An electric energy allocation method is further provided to realize the controllable electric energy transfer among batteries, power generation devices and electrical loads.

A system for balancing battery cell charge in a battery array for an electrified machine is provided. The battery array includes a plurality of individual battery cells, or groups of battery cells. A plurality of cell monitors are in communication with the individual battery cells, or groups of battery cells, with the plurality of cell monitors being powered by the individual battery cells, or groups of battery cells. A battery controller of the system receives information about the individual battery cells, or groups of battery cells, from the plurality of cell monitors. The information traverses the plurality of cell monitors in a first pattern to the battery controller and, after a predetermined period of time or occurrence of a predetermined event, the information traverses the plurality of cell monitors in a second pattern that is different than the first pattern to the battery controller.

The present disclosure relates to a hybrid power pack. The hybrid power pack includes a first storage component, a second storage component, a battery management system, a cell balancing circuit, a capacitor balancing circuit, a bidirectional switch, a unipolar transistor, an inout port, a first unidirectional switch and a second unidirectional switch. The hybrid power pack can provide sustained DC power to a load, drawing power selectively from the first storage component, the second storage component or from both storage components simultaneously.