A storage system includes: a plurality of storage batteries different in SOH from each other; and a charge/discharge controller configured to receive SOH information for specifying the SOH of each of the plurality of storage batteries and control charge/discharge of the plurality of storage batteries based on the SOH information so as to reduce a difference in SOH between the plurality of storage batteries.

In a storage system including a plurality of battery units, the charge/discharge amounts of the battery units are determined by predetermined computation using the state of charge (SOC). The predetermined computation includes allocating a larger discharge amount to a battery unit higher in SOC, out of the battery units, in the discharge mode, and allocating a larger charge amount to a battery unit lower in SOC, out of the battery units, in the charge mode.

Disclosed are an automobile, and a power battery pack equalization method and device, the method comprises the following steps: acquiring a high voltage inflection point of the charging curve of a battery cell of the power battery pack and acquiring the capacity of the battery cell according to the high voltage inflection point of the battery cell, and equalizing the battery cell according to the capacity of the battery cell. Hence, equalization management of the power battery pack can be realized, thereby improving the use ratio of the power battery pack and prolonging the service life of the power battery pack.

A battery protection integrated circuit which is used to construct a system configured to serially communicate among a plurality of the battery protection integrated circuits, the battery protection integrated circuit includes: a higher-level transmission terminal; a lower-level reception terminal; an acquisition device configured to acquire transmission information to transmit to the higher-level circuit; and a storage configured to store at least one of transmitted information transmitted from the lower-level circuit and the transmission information acquired by the acquisition device, the battery protection IC being configured to transmit, in response to reception of instructive information indicating an instruction for the higher-level circuit to read the transmitted information, one of the transmitted information and the transmission information from the higher-level transmission terminal to the higher-level circuit, and simultaneously receive, by the lower-level reception terminal, transmitted information transmitted from the lower-level circuit after the transmitted information.

A method for balancing a battery assembly includes selecting, from a plurality of batteries of the battery assembly in a charging state, one or more batteries based on a status of the plurality of batteries; and controlling charging of the selected one or more batteries for balancing the plurality of batteries. Battery balancing can be energy-efficient and time-efficient. The lifetime of the battery assembly can be extended.

The present disclosure comprises devices and methods used to regulate the power, voltage and/or current out of an individual energy storage module. A plurality of energy storage modules and/or individual interconnected energy storage modules can form an energy storage system when interconnected in series, parallel or series/parallel. The present disclosure also provides a method for storing and delivering energy, comprising providing an energy storage module for boosting the voltage of the energy storage component while delivering power to a load.

The present disclosure relates to methods and systems for management and control of interconnected energy storage modules, such as battery packs, that can form a larger energy storage system. The disclosure also relates to methods and system for the measurement of cell impedances in a battery pack in-situ and on-line and using active balancing circuits that may already be present in the battery pack. The methods and systems can inject disturbances of different frequencies and measure impedance by using the active balancing circuits present in the battery pack, which can transform an active balancer into a dual active balancer and impedance measurement system. The speed up of impedance measurement energy storage modules can be accomplished by using multi-tone, orthogonal or spread spectrum waveforms applied simultaneously on all or a sub-set of the active balancer circuits in an active balancer.

Systems and methods are disclosed that are related to a set of reconfigurable energy storage modules that can be assisted by an algorithm used to create larger energy storage systems in a flexible and efficient manner. The modules can interconnect in series, parallel or series/parallel and achieve balancing of the energy in every module while providing terminal voltage and/or current control and regulation. The modules can reconfigure on-the-fly and behave as a regular battery, a by-passing unit with a very low resistance, or a module capable of bucking or boosting voltage.

A battery monitoring device includes: an oscillator causing an AC signal to flow in the battery cell; a subtractor acquiring voltage fluctuation of the battery cell when the AC signal flows as a response signal; and a calculation unit calculating complex impedance. The calculation unit calculates the complex impedance based on a multiplication value X of the response signal and a first reference signal outputted in synchronization with the AC signal, and a multiplication value Y of the response signal and the second reference signal obtained by shifting the phase of the AC signal. The AC signal is a rectangular wave signal, the first reference signal is a rectangular wave signal outputted in synchronization with the AC signal, and the second reference signal is a rectangular wave signal, the phase of which is shifted so as not to be outputted overlapping with the first reference signal.

A power supply apparatus, that can wirelessly supply power to a plurality of power receiving apparatuses, comprises: a plurality of antennae; and a control unit, wherein the control unit carries out control so that information pertaining to sending timings of calibration signals is sent, via the plurality of antennae, to the plurality of power receiving apparatuses; the control unit carries out control so that calibration signals sent from the plurality of power receiving apparatuses are received via the plurality of antennae; and the control unit controls an output of each antenna based on the calibration signals sent from the plurality of power receiving apparatuses so that power is supplied wirelessly to the plurality of power receiving apparatuses from corresponding ones of the plurality of antennae.