A utility vehicle includes a plurality of ground-engaging members, a frame supported by the ground-engaging members, a powertrain assembly supported by the frame which includes an engine, an alternator coupled to the engine through a housing, and a heating, ventilation, and air condition (“HVAC”) assembly including a compressor operably coupled to the engine. The compressor is supported on a first side of the housing plate and the alternator is supported on a second side of the housing.

A electric vehicle including a plurality of ground engaging members, a frame assembly supported by the plurality of ground engaging members, the frame assembly including a front frame assembly, a middle frame assembly, and a rear frame assembly, a seating area supported by the middle frame assembly, electric powertrain components supported by the frame assembly to provide power to at least one ground engaging member, and a shrouding assembly.

A electric vehicle including a plurality of ground engaging members, a frame assembly supported by the plurality of ground engaging members, the frame assembly including a front frame assembly, a middle frame assembly, and a rear frame assembly, a seating area supported by the middle frame assembly, electric powertrain components supported by the frame assembly to provide power to at least one ground engaging member, and a shrouding assembly.

A panel includes a standoff formed from a wall extended in a height direction from an exterior surface of the panel. The wall is formed from a first wall section and a second wall section that is offset from the first wall section in a lateral direction of the panel along the exterior surface of the panel. A stopper hole is defined in the panel and extended in the height direction, in parallel with the first wall section and the second wall section, from the exterior surface of the panel. The stopper hole receives a stopper. The stopper hole is interposed between and separates the first wall section and the second wall section along the exterior surface of the panel, or is offset from the wall of the standoff in the lateral direction of the panel along the exterior surface of the panel.

A panel includes a standoff formed from a wall extended in a height direction from an exterior surface of the panel. The wall is formed from a first wall section and a second wall section that is offset from the first wall section in a lateral direction of the panel along the exterior surface of the panel. A stopper hole is defined in the panel and extended in the height direction, in parallel with the first wall section and the second wall section, from the exterior surface of the panel. The stopper hole receives a stopper. The stopper hole is interposed between and separates the first wall section and the second wall section along the exterior surface of the panel, or is offset from the wall of the standoff in the lateral direction of the panel along the exterior surface of the panel.

A sensor device for contactlessly determining a revolution rate and a direction of rotation of a component that rotates during operation of the component, the component having, on at least one peripheral region, a circumferential structure of web-shaped or tooth-shaped radial protrusions and interposed grooves or tooth gaps includes: a threaded segment configured to positionally fix an arrangement of the sensor device so that the circumferential structure of the component is movable past the sensor device; a magnetic field generating device; and a magnetic field detecting device having at least three magnetic field sensors that are not arranged in alignment along a line. A distance between the magnetic field sensors that are the farthest apart from each other is less than or equal to a width of the grooves or tooth gaps of the component.

A sensor device for contactlessly determining a revolution rate and a direction of rotation of a component that rotates during operation of the component, the component having, on at least one peripheral region, a circumferential structure of web-shaped or tooth-shaped radial protrusions and interposed grooves or tooth gaps includes: a threaded segment configured to positionally fix an arrangement of the sensor device so that the circumferential structure of the component is movable past the sensor device; a magnetic field generating device; and a magnetic field detecting device having at least three magnetic field sensors that are not arranged in alignment along a line. A distance between the magnetic field sensors that are the farthest apart from each other is less than or equal to a width of the grooves or tooth gaps of the component.

A universal traction device for movement over even and uneven supporting surfaces that includes an all-terrain wheel having a circular wheel assembly with a plurality of spoke-containing components arrayed around an outer perimeter wheel edge and control means for extending spokes from the spoke-containing units when encountering an obstacle that the vehicle is to traverse and retracting the spokes when the spokes are no longer required for traversing the obstacle.

Proposed is a modular driving apparatus which is driven in combination with at least one ride module or is driven independently by being combined with or separated from the ride module. The modular driving apparatus includes: a main body including a coupling space in which the ride module is mounted, and wheel modules which surrounds both sides of the ride module mounted in the coupling space and operates to run together with the mounted ride module or operates to run autonomously; and coupling guide blades which are respectively fastened to both sides of the main body and respectively include wheel module coupling holes for exposing the outer surfaces of the wheel modules.

An object of the instant application is to provide a vehicle that can minimize parking space and a parking facility that can efficiently park a large number of vehicles in a predetermined parking space. The vehicle 1 includes a bottom flap 7 arranged on a bottom surface of a vehicle body and vertically rotatable around a lower rear end of the vehicle body, a rear flap 8, and geared motors 9, 11 for respectively rotating the bottom flap 7 and the rear flap 8. The parking facility 20 for a vehicle 1′ is configured to include an erecting mechanism (a rotating member 22, an electric motor 23, and a link mechanism 24) for erecting the vehicle 1′ upright with a rear surface facing down, and a transfer mechanism (belt conveyor) 25 for transferring the vehicle 1′ erected by the erecting mechanism to a predetermined position.