The present invention discloses an outdoor electrical system and method based on a programmable power supply, pertaining to the field of outdoor electrical appliance, wherein the programmable power supply receives a data request signal from an outdoor electrical appliance, dynamically adjusts the output voltage based on the data request data, and then outputs it to the outdoor electrical appliance; when the output power of the outdoor electrical appliance is greater than a preset threshold, the power supply output is directly output to the electrical load through a set programming and protection detection module, and when the output power is less than the preset threshold, the power supply output is adjusted through a set low power conversion module before being output to the electrical load, which achieves that the energy conversion is completed in one step within the programmable power supply, without the need for a DC-DC conversion circuit in between, effectively reducing the number of energy conversions on the power consumption side, achieving the effect of reducing energy conversion loss, and enhancing the output conversion efficiency of the outdoor electrical system.

Provided is a charging system including: a second power transmission unit; a moving mechanism that moves the second power transmission unit within a moving area including prescribed ranges within a plurality of parking spaces; and a power transmission control unit that, when a first electric vehicle is parked in a first parking space as one of a plurality of parking spaces, moves the second power transmission unit into the prescribed range of the first parking space by the moving mechanism to cause the first power transmission unit mounted to a first electric vehicle and the second power transmission unit to face each other so as to transmit power to the first power transmission unit from the second power transmission unit wirelessly to execute vehicle charging processing for charging the first electric vehicle.

The present invention discloses a charging and discharging control method and system for an electric vehicle based on virtual synchronization, and relates to the technical field of virtual synchronization. The method includes: establishing connection between a power grid and the electric vehicle, and acquiring a charging and discharging operation demand; acquiring, according to the charging and discharging operation demand, a corresponding control instruction and constraint condition, and executing a charging and discharging operation; and providing a human-computer interaction interface for measuring and settling charging and discharging energy, along with authentication. The present invention achieves efficient and coordinated charging and discharging control, precise measurement and convenient authentication, and improves availability and reliability of the system.

A charging system includes a voltage conversion circuit, a control circuit, an input end Vin and an output end Vout. The voltage conversion circuit and the control circuit are connected to M batteries, the input end Vin is connected to an external power supply, and the output end Vout is connected to a load. The control circuit is configured to switch a connection relationship between the M batteries, to connect at least one of the M batteries to the voltage conversion circuit, where the connection relationship includes at least one of a serial connection or a parallel connection. The voltage conversion circuit is connected to the input end Vin and the output end Vout; is configured to receive power from the external power supply through the input end Vin, and charge the at least one battery; and is further configured to supply power to the load through the output end Vout.

A lawn mower includes a drive wheel, a mowing deck including a cutting blade, a wheel motor operable to rotate the drive wheel, a cutting blade motor operable to rotate the cutting blade, and a battery system. The battery system includes a battery configured to power the wheel motor and the cutting blade motor and a battery controller communicably coupled to the battery. The battery controller includes one or more processors and memory storing instructions that, when executed by the one or more processors, cause the one or more processors to determine an electric current threshold for the battery, broadcast a message comprising the electric current threshold, compare an actual electric current of the battery to the electric current threshold, and adjust an operation of the battery system in response in response to determining that the actual electric current of the battery exceeds the electric current threshold for a predetermined amount of time.

A battery pack assembly configured to supply power to a common load includes a backpack wearable on a back of a user, at least one battery arranged in the backpack and electrically coupled to the common load via a tether, and a communications interface operable between the battery pack and the common load. The communications interface is configured to perform one or more operations, including but not limited to receiving and transmitting operational information to and from the battery pack and the common load, the operational information relating to at least one of the battery pack or the common load.

An apparatus and a method for an aerosol generating device is described, the apparatus including a charging controller. The charging controller is configured to control charging of a battery using a power supply at a charging current dependent, at least in part, on power capabilities of the power supply.

A system for managing transferring of electrical power includes a power converter and a controller. The power converter is configured for receiving input power from a power source through a first connector, converting the input power to output power using a power conversion information based on the receiving, and supplying the output power to a power storage device through a second connector based on the converting. The power storage device includes an ultra-wideband gap semiconductor material. The supplying of the output power includes charging the power storage device based on the output power and the ultra-wideband gap semiconductor material. The power storage device stores power based on the charging. The controller is communicatively coupled with the power converter. The controller is configured for generating the power conversion information.

A charging case having one or more charging docks for charging one or more earbuds. The charging case can further have UV LEDs for automatically sterilizing the earbuds while charging.

A ring includes a housing. The housing can include an inner surface configured to contact a finger of a user when the housing is worn by the user. The housing also can include a first power source configured to be wirelessly charged by a second power source that is removably coupled to the housing. The housing further can include a component configure to draw energy from the first power source. The component can perform one or more of: sensing an activity of the user wearing the housing or sending data to a communication device. Other embodiments are disclosed.