A vehicle with a front wheel and a front wheel of a vehicle is provided. The front wheel is drivable by a first drive arrangement, and a rear wheel of the vehicle is drivable by a second drive arrangement. The first drive arrangement may be integrated into the front wheel, and includes an electric motor for selectively rotatably driving the front wheel, a reduction gear between the electric motor and the front wheel, and an actuable coupling for selectively coupling or decoupling the electric motor to the reduction gear.

A two-wheeled motor vehicle includes: a vehicle body frame; a rear wheel unit swingably supported on the vehicle body frame; a fuel cell unit supported on the vehicle body frame; a fuel tank extending rearwardly from the fuel cell unit over the rear wheel unit; and a secondary cell that is charged with electric power from the fuel cell unit and disposed below the fuel cell unit and the fuel tank.

A maneuvering system is provided for single- or multi-tracked vehicles. The system includes an electric motor and an output system which can be coupled to a vehicle transmission so that with the help of the electric motor the vehicle can be moved at least backwards. The electric motor is connected to the output system by a flexible shaft or a drive shaft.

A maneuvering system is provided for single- or multi-tracked vehicles. The system includes an electric motor and an output system which can be coupled to a vehicle transmission so that with the help of the electric motor the vehicle can be moved at least backwards. The electric motor is connected to the output system by a flexible shaft or a drive shaft.

The air intake structure for a saddle-ride type vehicle includes a front cowl, a pair of right and left air duct portions, an air cleaner box, and a vehicle body frame. The front cowl includes a pair of right and left air intake ports. The pair of the right and left air duct portions guides air taken from the pair of the right and left air intake ports. The air cleaner box cleans the air guided by the pair of the right and left air duct portions. The vehicle body frame is branched backward from a steering head pipe disposed on a front side of a vehicle into a bifurcated shape with a pair of right and left. The vehicle body frame includes the air cleaner box between the branches of the bifurcated shape. The air duct portion includes a first air duct and a second air duct. The first air duct guides air to the air cleaner box from the air intake port through the vehicle body frame. The second air duct branches from the first air duct in a middle to guide air to the air cleaner box.

A removable protective cover for engines and/or transmissions includes a central portion and a flexible peripheral flange that extends transversely from the central portion. The peripheral flange includes an engagement surface formed by a groove or other suitable feature on an inner side of the peripheral flange. A plurality of teardrop shaped washers or retainers have protruding portions that engage the groove to removably retain the cover on the engine. At least a portion of the peripheral flange comprises an elastomeric material such that the removable cover can be installed and removed by flexing the peripheral flange to cause the teardrop shaped washers to engage and disengage the groove.

There is provided a saddle-ridden type fuel cell vehicle. The fuel cell vehicle includes: a body frame; a steerable wheel; a driving wheel; a motor; a fuel cell; a fuel tank; and a tank valve. The body frame includes: a head pipe; a down frame portion; a pair of upper main frame portions; a pair of lower main frame portions; and up frame portions. A tank placement portion is formed in a region encircled by the upper main frame portions and the lower main frame portions in the middle portion of the body frame in the front and rear direction. The fuel tank is placed on the tank placement portion so that an axis thereof extends in the front and rear direction. A guard frame is installed between the up frame portions to traverse the rear of the tank valve in a right and left direction.

There is provided a saddle-ridden type fuel cell vehicle. The fuel cell vehicle includes: a body frame; a steerable wheel; a driving wheel; a motor; a fuel cell; a fuel tank; and a tank valve. The body frame includes: a head pipe; a down frame portion; a pair of upper main frame portions; a pair of lower main frame portions; and up frame portions. A tank placement portion is formed in a region encircled by the upper main frame portions and the lower main frame portions in the middle portion of the body frame in the front and rear direction. The fuel tank is placed on the tank placement portion so that an axis thereof extends in the front and rear direction. A guard frame is installed between the up frame portions to traverse the rear of the tank valve in a right and left direction.

An engine unit of a motorcycle has a crankcase and an overlying cylinder block. The crankcase has a magnet cover positioned outward of the cylinder block in the vehicle width direction as seen in the front-rear direction. The clutch actuator motor serving as a driving power source for a switching operation of the clutch is disposed inward of the side surface of the magnet cover in the vehicle width direction as seen in the front-rear direction. A part of the clutch actuator motor is positioned over the magnet cover.

The present invention is an electronic gear-shifting system with sound effects and display, adapted to be mounted on an electric motorcycle, and including an electronic shift unit, an electronic clutch unit, a throttle position sensor, correspondingly outputting a shift signal, a clutch signal and a throttle position signal according to the operation of the rider, a control unit receiving the aforementioned signals to determine a target gear position of the electric motorcycle and control a power motor of the electric motorcycle. The electric motorcycle converts the real speed of the power motor into a virtual speed through an algorithm and lets a dashboard and a sound effect controller of the electric motorcycle output according to the virtual speed. In addition to simulate the power performance of a general gear-shifting-type motorcycle, the electric vehicle also has visual and auditory variations.