Abstract: An electric vehicle includes a frame unit and a vehicle body cover unit. The frame unit includes tread tubes extending toward a rear side of a vehicle body and arranged pairwise as a left tread tube and a right tread tube. The vehicle body cover unit includes a tread board that shields the left and right tread tubes. The frame unit receives a battery box that receives and holds therein a battery and has two sides provided with support shafts to be pivotally supported thereon. The battery box is shaft-supported by the support shafts on the frame unit. The battery box includes a battery access opening, which is provided with a protection cover that covers and closes the battery access opening. The battery is securely held in the battery box without being moved by inertial forces. Dust resistance of the battery box can be improved.

Abstract: An accessory component for a vehicle is disclosed which may incorporate an elongated frame element having an elongated channel formed there along. The elongated frame element is adapted to be fixedly secured to a portion of the vehicle. A resilient metallic applique having a contour generally in accordance with at least a portion of the elongated frame element may be incorporated. The applique may have a feature adjacent a first end for engaging with the elongated channel, and a second end of the applique may be shaped to engage with a different portion of the elongated frame element such that the applique is secured to the elongated frame element without adhesives or mechanical fasteners.

Abstract: A power supply device includes a boost convertor configured to perform a boost-up operation to boost a voltage supplied from an input terminal, a connection-assist diode connected in parallel to the boost convertor between the input terminal and an output terminal, and a switching element connected in parallel to the boost convertor and the connection-assist diode between the input terminal and the output terminal. A controller instructs the switching element to open and instructs the boost convertor to perform a boost-up operation for boosting the voltage at the input terminal during a boost-up period. The controller instructs the boost convertor to stop the boost-up operation when the boost-up period elapses. The controller then instructs the switching element to close the switching element. The controller then determines a state of the switching element based on a voltage at the output terminal detected.