A control method of a fuel cell vehicle comprises estimating a load applied to an own vehicle that is the fuel cell vehicle and that runs on an estimated route by using current traffic flow information or the like in addition to the estimated route; determining whether an overload area is present on the estimated route by using the estimated load; and when it is determined that the overload area is present on the estimated route, performing an increasing process of increasing a cooling power of a cooling system to be greater than a cooling power set in an ordinary control mode before the own vehicle reaches the overload area.

A vehicle includes a control device including a first processing section, a second processing section, and a third processing section. The first processing section is programmed to acquire an excessive processing power of a general purpose computing device. The second processing section is programmed to cause the general purpose computing device to process a computing task stored in a first memory storage section and allow the processing result to be stored in a second memory storage section if the excessive processing power acquired by the first processing section is greater than a predetermined processing power. The third processing section is programmed to send the processing result stored in the second memory storage section to an external server by use of a communication device.

A vehicle includes a control device including a first processing section, a second processing section, and a third processing section. The first processing section is programmed to acquire an excessive processing power of a general purpose computing device. The second processing section is programmed to cause the general purpose computing device to process a computing task stored in a first memory storage section and allow the processing result to be stored in a second memory storage section if the excessive processing power acquired by the first processing section is greater than a predetermined processing power. The third processing section is programmed to send the processing result stored in the second memory storage section to an external server by use of a communication device.

The electrical discharge circuit (106) includes: two interface terminals (B.sub.A, B.sub.B), to which the capacitor (C) is intended to be connected and across which a capacitor voltage (u.sub.C) is intended to be present; a current-consuming electrical circuit (108) connected between the two interface terminals (B.sub.A, B.sub.B) and designed to consume a discharge current (i) from the capacitor (C); andan electrical control circuit (110) for controlling the current-consuming electrical circuit (108), the electrical control circuit (110) being connected between the two interface terminals (B.sub.A, B.sub.B) so as to receive the capacitor voltage (u.sub.C).

The electrical control circuit (110) is designed: to deactivate the current-consuming electrical circuit (108) when the capacitor voltage (u.sub.C) is above a predefined threshold; andto activate the current-consuming electrical circuit (108) when the capacitor voltage (u.sub.C) across the two interface terminals (B.sub.A, B.sub.B) is below the predefined threshold. The electrical control circuit (110) is furthermore designed to be supplied with electrical power exclusively via the two interface terminals (B.sub.A, B.sub.B).

A power supply control apparatus for an electric vehicle includes a main circuit including a smoothing capacitor connecting a power supply to an electric load driven by the power supply to smooth a fluctuation in an input voltage to the electric load, a main contactor interposed between the power supply of the main circuit and the electric load, and a precharge circuit connected in parallel with the main contactor and including a precharge contactor and a resistance element. When a timeout occurs before precharging by the precharge circuit is completed, the power supply control apparatus permits a retry of the precharging if the precharging is retried without any disadvantage.

An aircraft that includes a fuselage, an electric motor driven propulsion system, and a fuel cell system configured to provide electricity to the electric motor. The fuel cell system includes a fuel cell, a hydrogen tank, an oxygen tank, an air channel, and a cathode switch. The cathode switch being configured to convert between an air mode, wherein the fuel cell operates utilizing air from the air channel, and an oxygen mode, wherein the fuel cell operates utilizing oxygen from the oxygen tank.

A security strategy providing apparatus of a vehicle includes a communication circuit, a power controller, and at least one control circuit electrically connected to the communication circuit and the power controller. The at least one control circuit is configured to detect a connection of an external apparatus or an inflow of external data, and to block at least part of a function provided by the vehicle, at least part of power supplied by the power controller, or the at least part of the function and the at least part of the power, based on a detection result of the connection of the external apparatus or the inflow of the external data.

In a hybrid flight vehicle, having multiple rotors attached to a frame, a gas turbine engine to drive the rotors; a generator connected to the gas engine to generate electric power, a battery store the electrical power generated by the generator. multiple first electric motors connected to the rotors to drive the same by the electric power supplied from the battery, a second electric motor connected to the gas turbine engine to motor the engine by the electric power supplied from the battery and a control unit to control flight, wherein the control unit stops supply of the fuel to the engine when a detected residual of the battery is equal to or greater than a predetermined value, and supplies electric power to the second electric motor to motor the engine when a detected temperature of the engine is equal to or higher than a predetermined temperature.

Provided are a battery pack and a control method using the same, the battery pack having improved safety so as to prevent fire or prevent fire from spreading even if ignited, thereby reducing the risks which can occur during ignition. The battery pack, according to the present invention, comprises: an electrode assembly comprising an anode, a cathode, and a separator; and a single cell or a plurality of cells having a pouch-shaped battery case for accommodating the electrode assembly, wherein the cell is accommodated and stacked by the module case, the module case comprises a fire suppression agent or a fire extinguishing agent at the inner or outer part thereof such that the fire suppression agent or the fire extinguishing agent is automatically discharged from the module case when cell swelling occurs.

An electric vehicle includes a power storage device, a front compartment, a power supplying port, and an external power supplying device. The power storage device is configured to feed electric power to a motor for traveling. The front compartment is provided in front of a cabin of the electric vehicle in the electric vehicle. The power supplying port is provided in the front compartment and is configured to be connected with a power supplying cable. The external power supplying device is configured to feed electric power of the power storage device to an outside of the electric vehicle from the power supplying port.