This application provides a battery charging control method and device. Voltages of N cell units in an M.sup.th sampling period are obtained, and a voltage of the battery at each sampling moment among K sampling moments in said sampling period is calculated. Charging of the battery is stopped when the voltage of the battery increases monotonically in the M.sup.th sampling period and a trend of a fitting curve of the voltage of at least one cell unit among the N cell units in said sampling period is not rising.

A method for diagnosing at least one fuel cell stack of a fuel cell device by way of a fuel cell diagnostic system includes: impressing a sinusoidal first and at least one sinusoidal second AC current into the fuel cell stack; recording a sinusoidal first and second voltage response of the fuel cell stack; evaluating the first voltage response and evaluating the second voltage response by way of an analytical algorithm for a differential impedance analysis; determining a first resistance, a second resistance and a capacitance of the fuel cell stack by specifying an equivalent circuit diagram for the fuel cell stack; and diagnosing the fuel cell stack on the basis of the determined first resistance, the determined second resistance and the determined capacitance, wherein the diagnosis is carried out in real time. A computer-readable storage medium and a fuel cell diagnostic system are also described.

A monitor circuit for use in a management system with modular subsystems includes: a sensor configured to measure parameter values of a monitored electrical component as a function of time; and storage coupled to the sensor and configured to store the parameter values. The monitor circuit also includes frame preparation circuitry coupled to the storage and configured to prepare frames that include the parameter values, wherein the prepared frames vary in length as a function of time.

Provided is an electric storage device including: an electric storage unit; a temperature measurement unit that detects the temperature of the electric storage unit; a current measurement unit that measures the charge/discharge current of the electric storage unit; and a safety evaluation unit that calculates the safety evaluation value of the electric storage unit, where the safety evaluation unit determines a temperature range to which the temperature detected by the temperature measurement unit belongs among multiple temperature ranges, and calculates a safety evaluation value, based on the temperature range as a result of the determination and an accumulated value of a value related to the charge/discharge time of the electric storage unit.

A power unit operable to power equipment, the power unit including an electric motor, multiple removable and rechargeable battery packs, multiple switching elements, and a control unit. Each of the switching elements is connected between one of the battery packs and the electric motor and operate in one of an open position or a closed position. The control unit is operable to manage the position of the switching elements. The control unit is configured to determine whether one or more battery packs are supplying power for the electric motor, measure a voltage of each of the battery packs, determine whether each of the voltage measurements is within a predetermined value to each other, calculate a pulse width modulated (PWM) signal for each of the switching elements, assign each PWM signal to one of the switching elements, and apply each of the PWM signals to the assigned switching element.

A remaining capacity estimation apparatus includes a storage processing unit and a calculation unit. The storage processing unit acquires a model from a model generation apparatus and stores the model in a model storage unit. When data for updating the model are acquired from the model generation apparatus, the storage processing unit updates the model stored in the model storage unit. The calculation unit calculates a remaining capacity of a storage battery managed by the remaining capacity estimation apparatus by using the model stored in the model storage unit. At this time, data (measurement data for calculation) input to the model include a current, a voltage, and a temperature of the storage battery. When the input data when generating the model are only a current, a voltage, and a temperature, the measurement data for calculation are only a current, a voltage, and a temperature.

A vehicle includes a controller that, during a predefined period of time and responsive to an average current of the battery exceeding a first current threshold for a first period of time, reduces a maximum current threshold of the battery by a first amount, and during the predefined period of time and responsive to the average current exceeding a second current threshold for a second period of time, further reduces the maximum current threshold by a second amount.

A power storage system includes: a battery; a voltmeter; an ammeter; and processing circuitry. The processing circuitry functionally includes: a first calculation unit configured to calculate estimated internal resistance, which is an estimated value of present internal resistance, based on the voltage and the current; a second calculation unit configured to calculate charging power upper limit, based on the estimated internal resistance calculated by the first calculation unit, the present voltage, and the present current; a charge control unit configured to control charge of the battery to prevent charging power exceeding the charging power upper limit from being supplied to the battery; and a limitation unit configured to determine, based on the current, whether power fluctuation in which output power of the battery fluctuates greatly within a short period of time has occurred or not and to prohibit the second calculation unit from operating during the power fluctuation.

Processing circuitry associated with an implantable medical device (IMD) may store a value of a shared voltage as a battery voltage threshold. A shared voltage is a voltage magnitude at which the voltage curves for the population of batteries converge at a particular percent depth of discharge (% DoD). The shared voltage is a consistent voltage magnitude across the population of batteries. Based on the indication that the battery has reached the shared voltage, the processing circuitry may determine any or all of: the battery % DoD level, the amount, e.g., the percent of electrical energy remaining in the battery and the amount of time remaining before the battery reaches its end of service life. In some examples, the processing circuitry may output an elective replacement indicator based on the calculated amount of time remaining before the battery reaches its end of service life.

The disclosure relates to a method for monitoring battery cells and continuously providing cell aging states of battery cells of a device battery. The method includes providing temporal cell-operating value profiles of operating values for each of the battery cells and determining cell aging states of each battery cell based on one or more aging state models, respectively, depending on cell-operating value profiles provided with a high temporal resolution, after a respective evaluation period. The method includes selecting a portion of the battery cells for continuously capturing the cell-operating value profiles with the high temporal resolution in the respective next evaluation period, and continuously providing the cell- operating value curves of the selected battery cells with the high temporal resolution in the next evaluation period, while for remaining battery cells of the device battery no operating values or cell-operating value curves with low temporal resolution are provided.