A roof coating sprayer including a cart assembly and a sprayer assembly. The cart assembly has a frame with a plurality of wheels. The frame has a sprayer support assembly with a lateral member, and vertical spray nozzle attachment members arranged along the lateral member. The attachment members each mount a spray nozzle and can be vertically and horizontally shifted relative to the lateral member. The roof coating sprayer can be pulled over the surface of a roof at a uniform rate, enabling a coating of a uniform thickness to be sprayed on the roof. Additionally, the cart assembly can be self-propelled, enabling a uniform rate of speed for the cart and thereby enabling uniform application of coating.

A roof coating sprayer including a cart assembly and a sprayer assembly. The cart assembly has a frame with a plurality of wheels. The frame has a sprayer support assembly with a lateral member, and vertical spray nozzle attachment members arranged along the lateral member. The attachment members each mount a spray nozzle and can be vertically and horizontally shifted relative to the lateral member. The roof coating sprayer can be pulled over the surface of a roof at a uniform rate, enabling a coating of a uniform thickness to be sprayed on the roof. Additionally, the cart assembly can be self-propelled, enabling a uniform rate of speed for the cart and thereby enabling uniform application of coating.

A parking robot for a transportation vehicle having a holding device for firmly holding a wheel of the transportation vehicle and housing at least one drive installation on two opposite sides. The drive installation has a height-adjustable running gear having at least one parking robot wheel and adjusts the holding device relative to the at least one parking robot wheel between a lowered and a raised position. The parking robot autonomously moves to a receiving position on the wheel of the transportation vehicle, in which receiving position the holding device firmly holds the wheel, and by adjusting the holding device to the raised position by the running gear, raises the firmly held wheel of the transportation vehicle relative to the respective parking robot wheels.

A parking robot for a transportation vehicle having a holding device for firmly holding a wheel of the transportation vehicle and housing at least one drive installation on two opposite sides. The drive installation has a height-adjustable running gear having at least one parking robot wheel and adjusts the holding device relative to the at least one parking robot wheel between a lowered and a raised position. The parking robot autonomously moves to a receiving position on the wheel of the transportation vehicle, in which receiving position the holding device firmly holds the wheel, and by adjusting the holding device to the raised position by the running gear, raises the firmly held wheel of the transportation vehicle relative to the respective parking robot wheels.

A three-wheeled vehicle is disclosed having a vehicle frame supported by front ground engaging members and a single rear ground engaging member. The vehicle includes an engine positioned forward of an operator area and a swing arm coupled to the single rear ground engagement member. The operator area of the vehicle may include seating for a driver and a passenger.

A three-wheeled vehicle is disclosed having a vehicle frame supported by front ground engaging members and a single rear ground engaging member. The vehicle includes an engine positioned forward of an operator area and a swing arm coupled to the single rear ground engagement member. The operator area of the vehicle may include seating for a driver and a passenger.

Provided is a vehicle power device including: an inner ring as a fixed ring, an outer ring as a rotary ring which is an outer ring rotation, and a bracket a knuckle for fixing an inboard side end portion of the inner ring removably with the electric motor disposed. The electric motor is of an outer rotor motor type, and the bracket includes a bracket base portion and a bracket cylindrical portion, the bracket base portion for being attached to the knuckle and fixed to the inner ring, the bracket cylindrical portion which extends from the bracket base portion toward an outboard side is located on an outer periphery of the outer ring via a radial gap and is provided with a stator disposed on an outer peripheral surface. The rotor of the electric motor is removably attached to the wheel mounting flange via a rotor casing.

A drive device (7) for a motor vehicle drive train of an electric vehicle has a plurality of electric machines (12, 13, 14) and a transmission, where different transmission ratios between an input shaft and an output side can be selected. In this case, a first electric machine (13) is connected to the input shaft of the transmission or can be connected thereto, and the output side of the transmission is coupled to at least one output drive (9, 10), which is used in the motor vehicle drive train to connect a respective drive axle of the electric vehicle. In order to achieve the highest possible driving comfort by means of this drive device (7), a second electric machine (14) is also permanently connected to the output side.

To increase the stiffness of a floor panel while maintaining a large foot space for a rear-seat passenger. A vehicle-body structure includes a floor panel constituting a floor provided with front-row and rear-row seats, and a center frame disposed to be higher than and away from the floor panel at a vehicle-width-direction central portion and extending in a vehicle front-rear direction. A recessed portion having a bottom surface on which the feet of a passenger sitting on the rear-row seat can be placed is formed at the floor panel. The floor panel includes a cross member extending in a vehicle width direction at a rear portion of the recessed portion. A rear portion of the center frame is connected to the cross member.

A drivetrain layout that includes a primary gear reduction, a continuously variable transmission (CVT), a peak torque limiting (PTL) device and a range box is provided. The primary gear reduction is operationally engaged to an output of a motor. The CVT includes a primary pulley and a secondary pulley. The primary pulley of the CVT is operationally engaged to the primary gear reduction. The primary gear reduction reduces a rotational speed of the output of the motor that is coupled to the primary pulley of the CVT. The range box is operationally engaged with the secondary pulley of the CVT. The range box is configured to coupled torque between the CVT and wheels of a vehicle. The PTL device in operational engagement between the secondary pulley of the CVT and the range box, the PTL device configured to protect the drivetrain layout from torque transients.