In an approach for selecting a battery charging rate, a processor, responsive to an electronic device with a rechargeable battery being connected to a battery charging device, identifies a current battery status of the rechargeable battery. A processor determines a disconnect time of the battery charging device. A processor determines a charge level required. A processor determines a charging profile based on the current battery status, the disconnect time of battery charging device, and the charge level required. A processor sends the charging profile to the battery charging device.

Provided is a device and the like capable of increasing the convenience in performance evaluation of a secondary battery. A battery performance evaluation device 100 evaluates the performance of a secondary battery 240 installed in an electronic apparatus 200 based on mutual communication between the electronic apparatus 200 and/or a charger 400, to which the electronic apparatus 200 is connected, and the battery performance evaluation device 100. Then, battery performance information Info(D) corresponding to the evaluation result is output to an output interface 204 of the electronic apparatus 200. Thus, a user can ascertain the performance evaluation result of the secondary battery 240 without the need to take the electronic apparatus 200 or the secondary battery 240 in a specialized institution or the like, thereby increasing the convenience for the user of the electronic apparatus 200.

A method to charge a personal-protection-device energy store for operating a personal protection device of a vehicle. The method includes a step of reading in a voltage value of a source energy store of the vehicle. In addition, the method includes a step of ascertaining a charging current for charging the personal-protection-device energy store with power from the source energy store, the charging current being ascertained, using the voltage value read in; and using the charging current for charging the personal-protection-device energy store.

The present invention is a system and method for formation and packaging of a rechargeable battery. Battery is packaged with multiple modules with each module containing cells of different sizes. A controller reads the state of charge of battery modules and if state of charge is low, battery modules with smaller cells are charged first. The system is comprising of battery modules with each module holding one size cells and the package holding modules of different cell sizes. It is possible to have each module formed with different cell sizes as well. Logics in the controller memory determines the recharging sequence of the battery modules and send charging command to recharging hardware.

Predictive rechargeable battery management is provided, which includes obtaining performance data on a battery cell of multiple rechargeable battery cells within a product, and comparing the performance data of the battery cell to statistical data on battery cell performance of a plurality of battery cells. Further, the managing includes determining, based on the comparing, that performance of the battery cell is trending away from the statistical data of battery cell performance of the plurality of battery cells. Further, the managing includes performing a battery-related action based on the performance of the battery cell trending away from that of the plurality of battery cells.

A wireless charging device has a controller and at least one coil that is positioned near the surface of the charging device and configured to transmit an electromagnetic field and a first driver circuit configured to drive the transmitting coil. The controller is configured to cause the driver circuit to provide a charging current to the transmitting coil, decode a request for lower transmission power from a modulation of the charging current, reduce the amplitude of the charging current in accordance with the request for lower transmission power when a temperature measured at a surface of the charging device is less than a threshold temperature, and initiate a cool down sequence when the temperature measured at the surface of the charging device equals or exceeds the threshold temperature. In one example, the request for lower transmission power may be provided in an ASK-modulated signal superimposed on the charging current.

A charging cable has a current sensor, a charging state indicator and logic circuitry to operate the indicator based on detected levels of current flow to a chargeable device. If the sensor detects current below a low threshold, the logic circuitry operates the indicator to indicate that the cable is not connected to any chargeable device. If the sensor detects current above a higher threshold, the logic circuitry operates the indicator to provide a perceptible output indicating that the cable is connected to the chargeable device and the current is charging the battery. If the sensor detects current at or above the low threshold but below the high threshold, the logic circuitry operates the indicator to provide a perceptible output indicating that the cable is connected to a chargeable device but is not charging the battery of the device, e.g., when the battery is, or is nearly, fully charged.

A method and to a device for charging a battery for a means of transport. The method comprises the steps of: ascertaining an open-circuit voltage of the battery (30) on the basis of a voltage ramp that is generated by a controllable DC-to-DC converter (40) that is electrically connected to the battery (30), ascertaining a differential internal resistance of the battery (30) on the basis of a predefined model for the differential internal resistance of the battery (30) and the open-circuit voltage, ascertaining a target value for an output voltage of the DC-to-DC converter (40) on the basis of the open-circuit voltage of the battery (30), a predefined charging current of the battery (30) and the differential internal resistance of the battery (30), and charging the battery (30) using the target value for the output voltage in the DC-to-DC converter (40).

A power tool including a battery pack interface configured to receive a battery pack. The battery pack interface includes one or more power terminals and one or more communication terminals. The power tool further includes a controller having an electronic processor. The controller is configured to receive, via the one or more communication terminals, a plurality of signals indicating a plurality of temperatures of the battery pack. The controller is further configured to determine, based on the signals, a battery pack type. The controller is further configured to control discharge of the battery pack based on the battery pack type.

The exemplified systems and methods provide fixed and exchangeable energy storage and delivery system in an electrified vehicle architecture with multi-mode controls. The exchangeable energy storage are configured to be optional and ultra-portable. The integration of fixed and exchangeable energy storage provides a vehicle configuration that is further optimized for size, weight, and convenience.