The present application describes systems and methods for authenticating rechargeable batteries in a rechargeable battery cabinet. The rechargeable battery cabinet may be a part of a large, scalable, distributed network of rechargeable battery cabinets, in which rechargeable battery cabinets may be removed or added based on consumer demand for fresh batteries. The system and methods may track the rechargeable batteries and where they are located in the rechargeable battery cabinets by first assigning a dynamic identification number, such that a rechargeable battery compartment does not need a static identifier. The system and method may allow for real-time reading of the status of rechargeable battery cabinets and rechargeable batteries in the system. Each rechargeable battery may have a static identifier to uniquely identify the rechargeable battery. This system and method allows for efficient scaling and identification of rechargeable battery within the system.

The present disclosure provides a charging system and method and a power adapter. The system includes: a battery; a first rectification unit, configured to output a voltage with a first pulsating waveform; a switch unit, configured to modulate the voltage with the first pulsating waveform; a transformer, configured to output a voltage with a second pulsating waveform according to the modulated voltage; a second rectification unit, configured to rectify the voltage with the second pulsating waveform to output a voltage with a third pulsating waveform; and a control unit, configured to output the control signal to the switch unit to decrease a length of a valley of the voltage with the third pulsating waveform such that a peak value of a voltage of the battery is sampled.

The present disclosure relates to a lighting device (100) comprising a lighting unit (102), at least one application unit (104), and a battery housing (106) comprising a first battery compartment (108) with a first electrical contact set (110) for accommodating and connecting a first battery and with a second battery compartment (112) with a second electrical contact set (114) for accommodating and connecting a second battery, wherein the first and second battery compartments are configured to force an exclusive spatial accommodation of only one of the first and second batteries in the battery housing at a given point in time. The lighting unit is electrically connected to the first electrical contact set for being powered by the first battery in a first operational mode and the application unit is electrically connected to the second electrical contact set for being powered by the second battery in a second operational mode.

Battery life cycle management is facilited with distinct visual cues of colors and color-coded combinations. The color-codes enable battery types and characteristics over the course of the life of the battery to be determined. The color-codes are based on a color system that indicates a performance rating of the batteries. A system for managing the color-coded batteries selects color-coded batteries for use based upon color, maintaining color based functionality, and color-coded battery indication for destruction of the battery at the end of its life cycle.

A charging device, in particular for machine tools, including a charging unit which in at least one operating state is provided for contactlessly charging at least one rechargeable battery unit, and which includes at least a first charging operating mode for transmitting electrical energy. The charging unit includes at least a second charging operating mode for transmitting electrical energy, the second charging operating mode differing from the first charging operating mode in at least one charging parameter.

A communication and heating system for electronic nebulizer and related products are provided. The communication and heating system includes a battery circuit and a nebulizer circuit. The battery circuit is coupled with the nebulizer circuit through a first electrode and a second electrode which are movable. The battery circuit includes a first chip and a battery. The nebulizer circuit includes a second chip and a heating device. The first chip is configured to communicate with the second chip to perform identity authentication when the battery circuit is coupled with the nebulizer circuit. The first chip is configured to control the battery to supply power to the heating device when the identity authentication is successful. In this way, convenience of information exchange between the battery and the nebulizer can be improved.

An electric power system includes a relay which is switched between an on state in which charging/discharging of a battery is permitted and an off state in which charging/discharging of the battery is inhibited, and an electronic control unit which controls switching of the relay between an on state and an off state based on a command from an electronic control unit. When a command for switching the relay from the on state to the off state is given from the electronic control unit to the electronic control unit, in a case where an abnormality occurs in the electronic control unit or in a case where an abnormality occurs in communication between the electronic control unit and the electronic control unit, the electronic control unit switches the relay to the off state.

An electronic device comprises a power receiving unit and a control unit. In a first mode in which the power receiving unit receives power from a first battery and does not receive power from a second battery, the control unit calculates a first operable time based on a plurality of information relating to the first battery acquired from the first battery, and calculates a second operable time based on information other than information of a discharge current of the second battery among a plurality of information relating to the second battery acquired from the second battery and the information of the discharge current of the first battery acquired from the first battery.

A rechargeable battery pack including at least one interface for establishing a mechanical and/or electrical connection of the rechargeable battery pack to a hand-held power tool and/or a charging device. The interface includes contact elements for the electrical and/or mechanical contacting of corresponding contact elements on the hand-held power tool and/or corresponding contact elements on the charging device, at least one contact element being a signal contact element electrically connected to a coding element. The rechargeable battery pack also includes a rechargeable battery pack electronics system configured for providing information regarding the rechargeable battery pack via the signal contact element, and storing at least in part in the coding element, and a microcontroller connected to the rechargeable battery pack electronics system in such a way that the microcontroller detects when information is called up at the signal contact element by a hand-held power tool and/or by a charging device.

An illustrative battery charging device may identify a battery to be charged, and charge the identified battery using charge settings that are optimized for the identified battery. In some embodiments, the battery charging device may determine the optimized settings based on monitoring charging performance and discharge activities of the battery over time. The battery charging device may exchange data with a battery management service device, such as by exchanging battery health information, battery settings, and/or other data. The battery charging device may determine charge setting and times to charge a battery that is intended to power an unmanned aerial vehicle to complete a flight path.