A vehicle having reduced drag A vehicle (such as a trailer) has at least one side channel in each side wall and at least two roof channels on either side of a central ridge. Surprisingly, it has been found that providing side channels which are asymmetric (in that the trough of the channel is closer to the top of the channel than the bottom) results in an improved drag coefficient (compared to symmetric channels), as does providing a pitched roof (compared to a flat roof). Furthermore, the combination of asymmetric side channels and a pitched roof gives even better results.

A trailer stand positionable by a shunt truck is disclosed. The trailer stand includes a leg assembly having a front pair of legs and a back pair of legs, the front pair of legs connected by a front cross support and the back pair of legs connected by a back cross support, a wheel assembly having a wheel assembly frame that has a first end and a second end, the first end connected to the back pair of legs, the second end retaining an axle, the axle rotatably retaining at least two wheels, a stepped assembly having a front end, a back end, a top, and a bottom, the front end connected to the front cross support, the back end connected to the back cross support, the top of the stepped assembly providing a plurality of landing areas for an end of the semi-trailer, and a lifting frame.

An aerodynamic system for a vehicle, includes: an air duct guiding air flow from a front compartment to the outside of the vehicle; and a rotating body mounted in the air duct and rotatable in the air duct. The rotating body may have a rotation axis along a transverse direction of the vehicle, and the rotating body may rotate around the rotation axis.

A hinge structure may comprise a first assembly including a central post with an outer surface and a first connector element on the central post for mounting on a first structure, a second assembly pivotally coupled to the first assembly and including a ring extending about the central post, a ring connector connected to the ring, and a second connector element on the ring for mounting on a second structure. A braking element may apply a selectable amount of resistance to pivot movement of the second connector element with respect to the first connector element and including a friction pad extending about a portion of the central post, a pressure band for pressing the friction pad against the central post, and a connecting structure connecting the ends of the band and being adjustable to move the ends closer toward each other and to relax the ends away from each other.

There is provided a truck, comprising a cab and a plurality of storage tanks secured behind the rear of the cab, wherein the storage tanks are configured to contain hydrogen gas. An energy conversion system is configured to receive hydrogen gas from the storage tanks and to convert the chemical energy of the hydrogen into mechanical or electric energy. A cooling arrangement is configured to cool the energy conversion system. A wall is provided behind the cab and laterally of the storage tanks, the wall having its main extension in a vertical plane, wherein said wall houses at least a part of said cooling arrangement.

A rear-end air guide device for a motor vehicle includes a rear spoiler having a spoiler surface and a rear wing arranged in a vehicle vertical direction above the rear spoiler. The spoiler surface faces toward the rear wing, and the spoiler surface facing toward the rear wing is adjustable in a vehicle longitudinal direction.

A drag reducing device includes an air flow turning component having a curved surface adapted to turn air flow passing over the curved surface, a first mounting component for connecting the air flow turning component to a rear door of the vehicle, and a second mounting component for connecting the air flow turning component to one of the opposite side walls of the vehicle. The mounting components are configured so that the air flow component is automatically in a deployed position when the rear door is closed, so the air flow turning component turns air flow passing along the side the vehicle inward to thereby reduce drag. The mounting components are further configured so that the air flow component is automatically stowed between the rear door and the vehicle side wall when the door is fully opened. The air turning component is sized for a minimal prominence when stowed.

The invention relates to a vehicle characterized in that it comprises a tractor having a chassis extending along a longitudinal axis supported by wheels, a cab mounted on a chassis, an air deflecting assembly installed on a roof of the cab, the air deflecting assembly having a shield and an adjustment mechanism configured adjust a rear height of the shield, a semi-trailer configured to be removably attached to the tractor, a mechanical measuring device comprising a first portion configured to be disposed on a semi-trailer roof, second and third portions adjacent to the semi-trailer front wall, the third portion configured to indicate an optimal position of the air deflecting assembly selected from among predetermined positions.

A trailer truck is the combination of a truck and one or more trailers used to haul freight. A trailer attaches to the truck via a trailer coupling (hitch), with much of its weight borne by the truck. The result is that both the truck and the trailer will have a distinctly different design than a rigid truck and trailer. Exemplary vehicles are provided, such as heavy duty trucks having truck bodies with improved aerodynamic characteristics, including improved drag coefficients.

A deployable fairing for a transport vehicle comprises a flexible, internally pressurizable enclosure supported by a structural frame. The structural frame comprises a plurality of rigid structural members forming at least two subframes that are pivotally coupled to one another and is foldably movable between a collapsed configuration and an expanded configuration. The enclosure moves with the structural frame, unfolds when the structural frame moves into the expanded configuration and folds in upon itself when the structural frame moves into the collapsed configuration. Moving the structural frame into the expanded configuration develops tension on at least part of the outer surface of the enclosure, and movement of the structural frame into the collapsed configuration releases the tension. When the enclosure is internally pressurized while the structural frame is in the expanded configuration, the outer surface of the enclosure is structurally stiff and conforms to a predefined aerodynamic shape.