A first electronic device receives a first operation, where the first operation is used to switch a power role in a charging process; and sends a first instruction to a second electronic device based on the first operation, where the first instruction indicates the second electronic device to switch to a charged device. Based on the first operation, the first electronic device adjusts the first signal line to be a signal line for the first electronic device to send data to the second electronic device, adjusts the second signal line to be a signal line for the first electronic device to receive data sent by the second electronic device, and adjusts an output voltage of the first electronic device to switch the first electronic device to a power supply device.

A process for transiently increasing performance of an electric motor includes boosting a DC link voltage of a rectifier-fed variable frequency drive of the electric motor by using an energy storage system. The energy storage system delivers power directly to a DC link of the variable frequency drive. The energy storage system can be at least one of a battery bank, capacitor bank and a flywheel. Feedback from the DC link is delivered to a DC link controller.

This disclosure introduces a method and a power consumption device which is configured to: connect to a power supply device through a cable, and control the power supply device to supply power to the power consumption device. Both the power consumption device and the power supply device support a first protocol and a second protocol. The method includes: controlling the power supply device to charge the power consumption device according to the first protocol, when it is determined that the power supply device supports the second protocol, controlling the power supply device to charge the power consumption device based on the charging parameter, and after controlling the power supply device to charge the power consumption device based on the charging parameter, controlling, based on obtained through-current capability information of the cable, the power supply device to charge the power consumption device according to the second protocol.

A system for charging a plurality of cordless power tool batteries includes charging circuitry and a plurality of docking stations. The charging circuitry includes a plurality of electrical connectors connectable to up to j>1 electrical loads, and primary control circuitry to direct DC output power to kj of the electrical connectors that are connected to kj electrical loads, separately and in succession. The plurality of docking stations are connectable to the plurality of electrical connectors as the kj electrical loads. Each docking station includes charging ports to receive up to m>1 of the cordless power tool batteries, and secondary control circuitry to direct the DC output power to recharge nm of the cordless power tool batteries that are received by the plurality of charging ports, separately and in succession under control of the primary control circuitry.

The present disclosure provides a voltage stabilizing circuit, a voltage stabilizing method, a charging circuit, and an electronic equipment. In the present disclosure, the voltage stabilizing circuit is designed to include multiple operating modes, which prevents a structure of simultaneously setting a boost converter and a buck-boost converter, thereby improving voltage conversion efficiency and reducing cost.

Systems and apparatus may carry out analysis of battery physical phenomena, and characterize batteries based on phenomena occurring in particular time and/or frequency domains. These systems may be additionally responsible for charging and/or monitoring a rechargeable battery. Examples of battery physical phenomena include mass transport (e.g., diffusion and/or migration) in battery electrolytes, mass transport in battery electrodes, and reactions on battery electrodes.

An apparatus includes first and second capacitors, first and second switches, a current source, a first circuit, and a second circuit. The first switch is coupled between a first terminal of the first capacitor and a reference terminal. The current source has an input coupled to a power terminal. The second switch is coupled between the first terminal of the first capacitor and an output of the current source. The second capacitor has a first terminal coupled to the reference terminal. The first circuit has a first terminal coupled to a second terminal of the second capacitor, and a second terminal coupled to a second terminal of the first capacitor. The second circuit has a first input coupled to a third terminal of the first circuit, a second input coupled to the power terminal, and an output coupled to the output of the current source.

A jobsite audio device with multi-source power and multi-port USB interface is proposed, which includes an AC-DC power source, a battery pack, a multi-port USB interface including at least one bidirectional power delivery USB C port, a charging circuit coupled to the AC-DC power source, the battery pack and the multi-port USB interface to provide power delivery paths, an audio module powered by the AC-DC power source or the battery pack to generate audio signals, and a main controller coupled to the charging circuit and the audio module, wherein the main controller monitors power consumption of the audio module and charging process of the charging circuit to automatically adjust charging power.

A charging system includes a charging input interface, an inductor, a first switch, a second switch, a first voltage acquisition circuit, and a control circuit. The charging input interface is connected to the inductor, which is connected to the first switch and the second switch. The second switch is configured for electrical connection with an energy storage power supply. The first voltage acquisition circuit is connected to the second switch and configured to detect the first voltage output by the charging system in real time. The control circuit cyclically controls the switch on/off time of the first switch based on the first voltage. During the charging process of the charging system, when the first voltage is less than the first preset voltage value, the control circuit controls the first switch to conduct and starts cyclic control. The state of the first switch is opposite to that of the second switch.

A battery control apparatus may include a power supply unit connected to a charging and discharging path of a battery, a driving unit configured to operate the power supply unit by applying a starting power to the power supply unit during a preset starting time from the charging and discharging path, a switching unit connected between the charging and discharging path of the battery and the power supply unit, and a control unit configured to turn on the switching unit in response to that a first operation power output from the power supply unit is applied, and to be driven through a second operation power generated by the power supply unit after the starting time.