An interleaved switched mode power supply and control method therefor are disclosed. The interleaved switched mode power supply includes a first switched mode power supply; a second switched mode power supply; and a controller. The controller controls the first and second switched mode power supplies so that the controller and the first and second switched mode power supplies form an interleaved switched mode power supply with power factor correction. The controller modulates a switching frequency of each of the first and second switched mode power supplies such that the switching frequency varies based upon ripple current cancellation between the ripple current of the first switched mode power supply and the ripple current of the second switched mode power supply.

A method of managing charging of a traction battery and corresponding devices, the traction battery including a thermal regulating system, the thermal regulating system including a compressor, the method including transmitting information between a control device for the compressor and a device for managing the charging of the traction battery, before activating the compressor or before activating a device for charging the traction battery.

A charging method and apparatus, wherein the method is applied to an electric vehicle, the electric vehicle includes a power battery and a fuel cell that are connected, and the method includes: when a function of idle charging of the fuel cell is started up, detecting, every preset duration, a first power-battery electric quantity of the power battery; calculating a second power-battery electric quantity that is required to start up the fuel cell; and when the first power-battery electric quantity and the second power-battery electric quantity satisfy a predetermined condition, charging the power battery. The present disclosure may enable the power battery to be charged when the predetermined condition is satisfied, to ensure that feeding of the power battery does not happen due to long-time placement of the power vehicle, which ensures the usage reliability of the power vehicle.

A charging method and apparatus, wherein the method is applied to an electric vehicle, the electric vehicle includes a power battery and a fuel cell that are connected, and the method includes: when a function of idle charging of the fuel cell is started up, detecting, every preset duration, a first power-battery electric quantity of the power battery; calculating a second power-battery electric quantity that is required to start up the fuel cell; and when the first power-battery electric quantity and the second power-battery electric quantity satisfy a predetermined condition, charging the power battery. The present disclosure may enable the power battery to be charged when the predetermined condition is satisfied, to ensure that feeding of the power battery does not happen due to long-time placement of the power vehicle, which ensures the usage reliability of the power vehicle.

An unmanned aerial vehicle (UAV) includes a fuselage, electronics disposed with the fuselage, a heat sink, and a solar shield. The heat sink is thermally connected to the electronics and includes a cooling plate disposed on or extends through an exterior surface of the fuselage. The cooling plate is exposed to an external environment of the UAV to conduct heat from the electronics to the external environment via convection. The solar shield extends over the cooling plate and defines an air scoop within which the cooling plate is disposed. The air scoop directs airflow from the external environment across the cooling plate. The solar shield shades the cooling plate from solar radiation to prevent or reduce solar heating of the cooling plate.

An unmanned aerial vehicle (UAV) includes a fuselage, electronics disposed with the fuselage, a heat sink, and a solar shield. The heat sink is thermally connected to the electronics and includes a cooling plate disposed on or extends through an exterior surface of the fuselage. The cooling plate is exposed to an external environment of the UAV to conduct heat from the electronics to the external environment via convection. The solar shield extends over the cooling plate and defines an air scoop within which the cooling plate is disposed. The air scoop directs airflow from the external environment across the cooling plate. The solar shield shades the cooling plate from solar radiation to prevent or reduce solar heating of the cooling plate.

A parking bay monitoring system for electric vehicles includes a main unit for each parking bay, a router being housed in the main unit and connects to a network, at least one digital camera mounted in a position to take digital images of a parking bay, wherein the digital images are transmitted via the router to a central server for analysis by a visual recognition framework to generate a detection result. The system further includes a charging unit, wherein real time data relating to charging is logged and transmitted to the central server, wherein an occupancy status for each parking bay is generated based on the detection result and said data. The system generates a list containing the occupancy status of each parking bay and the said list being accessible by at least one terminal connected to the network.

A system for an integrated energy pipeline with vehicle recharging or refueling stations is described. The system generates hydrogen gas from solar powered electrolyzers. The system distributes the hydrogen gas for the fueling of vehicles. The system generates the hydrogen gas locally from solar radiation and water provided to the system.

A system for connecting and disconnecting rail vehicle system for storing, transporting, and delivering bulk electric energy using railroads is described. The system includes. The system includes at least one rail vehicle system. The rail vehicle system includes a locomotive and a group of rail cars. The group of rails cars includes several rail cars with energy storage, power electronics and communication system. The rail car further includes a pantograph. The system also includes a plurality of electrical feeders. The electrical feeders are substantially dedicated for providing power transfer to and from the respective groups of rail cars. The system further includes at least one position controls system. The position control system is configured to be coupled to the geographical location of at least one electrical feeder, and it is substantially dedicated for aligning the geographical location of at least one group of rail cars with the geographical location of the respective electrical feeders for the group of rail cars. The system further includes energy management system for the controls of charging and discharging of onboard energy storage on the rail vehicle system.

A system for connecting and disconnecting rail vehicle system for storing, transporting, and delivering bulk electric energy using railroads is described. The system includes. The system includes at least one rail vehicle system. The rail vehicle system includes a locomotive and a group of rail cars. The group of rails cars includes several rail cars with energy storage, power electronics and communication system. The rail car further includes a pantograph. The system also includes a plurality of electrical feeders. The electrical feeders are substantially dedicated for providing power transfer to and from the respective groups of rail cars. The system further includes at least one position controls system. The position control system is configured to be coupled to the geographical location of at least one electrical feeder, and it is substantially dedicated for aligning the geographical location of at least one group of rail cars with the geographical location of the respective electrical feeders for the group of rail cars. The system further includes energy management system for the controls of charging and discharging of onboard energy storage on the rail vehicle system.