The invention relates to a charging station for electric vehicles, with a matrix output. The charging station comprises: at least two power blocks, each having at least two power modules; at least two charging points compliant with the corresponding outputs of the charging station provided with respective charging connectors; a switch matrix with a specific number of inputs and a number of outputs; a control unit and additional units. The invention also relates to a method for controlling the charging station.

The invention provides an electronic assembly for an automotive lighting device. the electronic assembly comprising a plurality of converters (8, 9, 10, 11, 12), at least one driver channel (5, 6, 7) being electrically fed by at least one converter (8, 9, 10, 11, 12) and a plurality of solid-state light sources (2, 3, 4). at least one solid-state light source receiving current and control from each driver channel (5, 6, 7). At least one of the converters (8, 9, 10, 11, 12) is arranged for selectively being connected or disconnected to provide different current values to at least one of the driver channels (5, 6, 7).

A system for an electrically-driven vehicle includes at least one first energy store, which is of an accumulator type, and at least one second energy store, of a type which differs from an accumulator type. The second energy store has an energy density lower than an energy density of the first energy store, and has a power density higher than a power density of the first energy store. The first energy store and the second energy store are designed to supply electrical energy for an electric drive of the vehicle.

The application discloses a power supply system for an smart toilet, which comprises: a controller power supply circuit, an assembly driving power supply circuit, a controller circuit and a driving component circuit, an input end of the controller power supply circuit is electrically connected with an external power supply, an input end of the assembly driving power supply circuit is electrically connected with the external power supply, an output end of the assembly driving power supply circuit is electrically connected with a power supply end of the driving component circuit, an output end of the controller power supply circuit is electrically connected with a power supply end of the controller circuit, an output end of the controller circuit is in communication connection with a control end of a switch control circuit of the assembly driving power supply circuit, and an output power of the controller power supply circuit is lower than that of the assembly driving power supply circuit. According to the application, when the smart toilet is not in use or is in a standby state, the output of the assembly driving power supply circuit is turned off, and only a controller power supply is retained to supply power, thus achieving an effect of energy consumption reduction and prolonging a service life of an assembly driving power supply.

A power supply system includes: a first power supply circuit for supplying, to a first load device, DC power output from a first main power source device; a second power supply circuit for supplying, to a second load device, DC power output from a second main power source device; a first connection circuit capable of connecting the first power supply circuit and the second power supply circuit to each other; and a first auxiliary power storage device connected to the first connection circuit in parallel with the first main power source device and the second main power source device.

Features are disclosed for charging a battery using a power supply in series with a diode. A power supply can be connected in series with a diode to restrict an inrush current resulting from connection of the power supply with a battery. In some embodiments, the power supply can further include a plurality of power supplies to restrict the amount of inrush current a single power supply can provide. In other embodiments, the power supply can also include a bypass capacitor that the power supply charges before supplying current to the battery. The power supply can regulate the amount of current that is applied to the battery and prevent inrush current from damaging the battery. Multiple power supplies add to overall reliability.

A battery cell having first cell connectors, a galvanic cell and a first switching unit electrically coupled to the first cell connectors and the galvanic cell for electrically coupling the galvanic cell to the first cell connectors depending on a switching state of the first switching unit. The battery cell has second cell connectors electrically separated from the first cell connectors and a second switching unit electrically coupled to the second cell connectors and the galvanic cell for electrically coupling the galvanic cell to the second cell connectors depending on a switching state of the second switching unit.

A charging/discharging system to provide a direct current (DC) distribution based charging/discharging system for a battery formation process, in which a large number of batteries is connected in common to a DC grid through charge/discharge equipment, alternating current (AC) power from an AC power network is converted to DC power required for the battery formation process and the DC power is outputted to the DC grid is provided.

A working method of a modular uninterruptible power supply (UPS) includes: obtaining working parameters of the modular UPS, where the working parameters include an input voltage parameter, a load parameter, and a battery parameter; and adjusting a working mode of a power module in the modular UPS according to at least one of the working parameters of the modular UPS, so that not all power modules are in a same working mode, where the modular UPS includes K working modules, and 2K.

The present disclosure relates to a method of controlling power supply units (1-9) of a base station (10), and a device (20) performing the method. In an aspect, a method of a base station scheduling device (20) of controlling power supply units (1-9) of a base station (10) is provided. The method comprises acquiring (S102a-c) information indicating a value of voltage input to at least one of the power supply units (1-9) of the base station (10), determining (S103) from said value if the voltage input to said at least one of the power supply units (1-9) is sufficient, and if not determining (S104) power demand of the base station (10), and deactivating (S105) said at least one power supply unit, if remaining power supply units (1-9) is capable of supplying the demanded power.