Abstract: In one example embodiment, a computer-implemented method for autonomous vehicle control includes determining whether a cargo container is attached to the vehicle base. The method includes controlling a front shield associated with an autonomous vehicle to move from a closed position to an opened position when a cargo container is determined to be attached to a vehicle base associated with the autonomous vehicle. The method includes controlling the front shield to move from the opened position to the closed position when the cargo container is not attached to the vehicle base.

Abstract: A drag reducing device for a vehicle body having a top wall and a door pivotably mounted to the rear of the body to open toward a side wall of the body, includes a wing sized and configured to turn airflow across the top wall of the body, the wing having a trailing edge and a proximal edge; and an assembly mounted to the door and configured for pivoting the wing so that the trailing edge of the wing is pivoted upward to a position above the top wall of the vehicle body when the door is open and for pivoting the wing so that the trailing edge of the wing is pivoted downward to a position below the top wall of the vehicle body when the door is closed.

Abstract: A vehicle having a wagon body which is supported on at least one running gear, wherein the wagon body defines a vehicle longitudinal direction, a vehicle transverse direction and a vehicle height direction. The wagon body has a body section and an adjacent head section. The head section has an outer skin and a flow separation unit for reducing sensitivity of the vehicle to crosswind. The flow separation unit comprises a roof-like protrusion formed by the outer skin. The roof-like protrusion has a first roof section, a second roof section, and a ridge section forming a transition between the first roof section and the second roof section. The first roof section and the second roof section run inclined to one another such that, the ridge section forms a flow separation edge for the air flow.

Abstract: An end carriage that extends between a first free end and a second end intended to be connected to another carriage of the railway vehicle, the end carriage including a lower housing for a bogie made in proximity to the first end. The end carriage further includes at least one conduit, opening on the one hand into the lower housing, and opening on the other hand into the first end of the end carriage, and means for circulating air in the conduit.

Abstract: An air deflector, and tractor-trailer rigs that use the air deflector, that includes a storage tube having a vertical slot, a shaft that is located within the storage tube, and a wind screen having a first end that is operably connected to the shaft and which extends through the vertical slot. A movable support rod is attached to the end of the wind screen that extends through the vertical slot. A torsion spring biases the wind screen toward retraction. Connecting hooks extend from the movable support rod. A mounting flange attached to the storage tube can connect the storage tube to a first trailer. A stationary attachment can connect to the tractor-trailer.

Abstract: Disclosed is a roof fairing for a vehicle, such as a truck hauling a trailer. The roof fairing includes a body defining a flow directing exterior surface. The body including at least one flow directing channel that is sunk into the body toward an inner space defined by an interior surface of the body. The flow directing channel comprises a venturi construction terminating at the trailing edge. The venturi construction is configured to direct flow toward an exterior surface of the trailer when coupled to the truck.

Abstract: A process of making a drag-reducing aerodynamic vehicle system includes injection molding a body configured for attachment to a roof of a vehicle with a sliding core, wherein the body comprises an air inlet extending through a surface of the body, wherein the air inlet includes an air guide boss extending from an interior surface of the body, wherein the air guide boss adjusts an air stagnation point away from the windshield to reduce air pressure and drag on the vehicle; and ejecting the drag-reducing aerodynamic vehicle system from the injection mold using the sliding core.

Abstract: Disclosed are a partition panel for vehicles and a method of manufacturing the same. The partition panel for vehicles includes a panel part formed of a composite material to divide a trunk and the inside of a vehicle from each other and a reinforcement part formed of a composite material, inclined upwards from the center of the lower portion of the panel part to both ends of the panel part, and connected integrally to the panel part.

Abstract: An aerodynamic control system includes a skirt assembly configured to be disposed between plural vehicles in a vehicle system formed from the plural vehicles with the vehicles separated by a spatial gap in the vehicle system. The skirt assembly can include a bladder configured to be inflated with a fluid by a fluid source disposed onboard the vehicle system to cause the skirt assembly to expand between the vehicles from a collapsed state to an expanded state such that the skirt assembly at least partially fills the spatial gap between the vehicles. The skirt assembly can reduce aerodynamic drag exerted on the vehicle system during movement of the vehicle system relative to the vehicle system moving without the skirt assembly in the expanded state.

Abstract: Disclosed are body panel strakes for improved vehicle aerodynamics, methods for making and methods for using such aerodynamic strakes, and motor vehicles employing aerodynamic strakes for reducing turbulent flow and developing higher static pressure at the rear of the vehicle. An underbody panel for a motor vehicle is disclosed. The motor vehicle includes a vehicle body with an undercarriage spanning between front and rear vehicle ends. The underbody panel includes a panel body that attaches to the vehicle body and covers a portion of the undercarriage. One or more elongated air strakes are attached to and project from the panel body. Each air strake includes an elongated body that extends longitudinally with respect to the vehicle and has an inboard-facing curvature. The air strake guides airflow traveling fore-to-aft along the undercarriage in an inboard direction to thereby increase static pressure on the rear end of the vehicle.

Abstract: Systems and methods are disclosed for providing a deployable fairing system to a tractor trailer. The deployable fairing system includes an actuator used to extend the deployable fairing from an unextended configuration to an extended configuration to occupy a portion of a gap area that exists between a tractor and an attached trailer. The deployable fairing includes deployable upper and/or lower horizontal assemblies that are pivotally coupled to a frame attached to the tractor/cab, and two side panels that are pivotally coupled to one or both of the upper and lower horizontal assemblies. The deployable upper and lower horizontal assemblies and the two side panels fold in on one another along multiple hinged axes in the unextended configuration, and extend rearward from the top and sides of the tractor in the extended configuration to cover a portion of the gap. The fairing may advantageously flair from front to the rear.

Abstract: An aerodynamic device provided as a plate-shaped body attached to a roof or a side wall of a vehicle includes means configured to selectively raise ribs arranged in two directions from a surface portion of the plate-shaped body in a switching manner between the two directions.

Abstract: A nose fairing for a cargo enclosure may generally include a nose body configured to extend outwardly from a front wall of the enclosure. The nose body may include an upper nose wall, a lower nose wall and a leading edge region extending between the upper and lower nose walls. The upper nose wall may include a concave region that terminates at the leading edge region such that the nose fairing transitions directly from the concave region of the upper nose wall to the leading edge region. The lower nose wall may include a convex region that terminates at the leading edge region such that the nose fairing transitions directly from the convex region of the lower nose wall to the leading edge region. The leading edge region may define a radius of curvature that differs from a radius of curvature of the convex region of the lower nose wall.

Abstract: An air guidance device for a turbomachine includes an air supply channel of a turbomachine engine. The supply channel has an upstream section and a downstream section connected together by a diverting section, the upstream section and the diverting section being connected together via an internal elbow and an external elbow. At the internal elbow, the internal surface has a groove extending longitudinally in the longitudinal direction of the supply channel and the longitudinal edges of which are widened in the direction of the downstream end of the upstream section of the supply channel.

Abstract: A suspension automobile comprising an automobile body, wheels and a flow disturbing plate, the wheels connect the flow disturbing plate through connecting devices, and a fluid channel communicating with the outside is formed between the upper surface of the flow disturbing plate and a bottom shell of the automobile body; a power device used for driving the automobile is contained in the body and is suspended along with lift force generated by the body. The invention changes the common sense that the wheels bear all weight generated by the self-weight, loads, and gravitational acceleration of the automobiles when traveling; the body which exceeds 90% by weight of the automobile generates lift force to suspend, the wheels eliminate lift force; meanwhile, a novel propelling force source is found from fluid resistance; the suspension automobile can be driven by various energy including engines and clean energy, thus effectively reduce energy loss.

Abstract: An automobile diffuser is the upwardly-ramped surface at the rear of the vehicle's underbody. Aerodynamic downforce and drag are generated as airflow travels underneath and along the ramped surface of the diffuser. However, with a moderate drag penalty, the downforce-producing effect of the diffuser can be further enhanced by an arrangement of aerodynamic devices along the ramp surface and within the diverging flow channel of the vehicle's diffuser.

Abstract: An apparatus is configured such that the outer shape of a shape memory material is transformed or changed to be enlarged or decreased in conjunction with vehicle speed and at that time a deflector 30 is actuated to move up and down to actively improve aerodynamic performance of a vehicle.

Abstract: A rectifying device includes: at least one front rectifying member that is disposed adjacent to projecting components on a rear side of a vehicle with respect to the projecting components to extend substantially along a vehicle width direction and project downward; and a rear rectifying member that is disposed at a center in the vehicle width direction on the rear side of the vehicle with respect to the front rectifying member to extend substantially along the vehicle width direction and project downward. The projecting components are disposed to at least partly project from an underside part of a vehicle body and provided as a pair apart from each other in the vehicle width direction.

Abstract: An aerodynamic control system for vehicles may improve aerodynamic performance of a vehicle and enhance fuel efficiency and driving stability of the vehicle. The aerodynamic control system includes a diffuser combined with a rear bumper at an ascending position so as to constitute part of a bumper surface of the rear bumper and separated from the rear bumper at a descending position so as to pass air exhausted from a lower part of the vehicle to a rear part of the vehicle along upper and lower surfaces of the diffuser, and a diffuser driving unit that connects a vehicle frame panel in a front of the rear bumper to the diffuser, supporting the diffuser on the vehicle frame panel, and adjusting upward and downward movement of the diffuser and the angle of the diffuser.

Abstract: A vehicle includes an engine generating exhaust gas flow and a vehicle body having a first body end facing oncoming ambient airflow when the vehicle is in motion and an opposite second body end. A vehicle underbody section spans a distance between the first and second body ends. A diffuser disposed at the second body end controls an underbody airflow portion past the second body end. An exhaust duct discharges the exhaust gas via a duct outlet arranged between the underbody section and the diffuser. A first diffuser aperture aligns with the duct outlet for discharging the exhaust gas from the outlet to the ambient. A second diffuser aperture pulls at least a fraction of the underbody airflow over the duct outlet and through the first aperture. The first and second apertures accelerate the pulled underbody airflow to increase a downforce on the vehicle body at the second body end.

Abstract: A rear fairing system for a vehicle includes a roof foil on top of the vehicle roof and sidewall foils pivotally mounted to the vehicle sidewalls. The roof foil includes downwardly facing concavity and a roof foil curved convex upper surface extending laterally across the vehicle roof. A spring extends laterally across the vehicle roof in the downwardly facing concavity. A door foil extends aft of the roof foil with a curved convex upper surface continuing the roof foil curved convex upper surface. Cables extend from the vehicle rear doors to the sidewall foils adjacent the sidewall foil free edges. The cables are taut and strain the sidewall foils toward the vehicle rear doors with the vehicle rear doors closed.

Abstract: A system of wake control for a ground vehicle to help promote increased fuel efficiencies of the ground vehicle by modifying an air flow wake generated during the movement of the vehicle in a forward direction. The system includes at least one slot jet configured to be located along a rear profile portion of the ground vehicle. The at least one slot jet is configured to provide a continuous flow of air at a non-zero velocity when the ground vehicle is moving in a forward direction, the non-zero velocity being at least partially directed in a rearward direction with an output velocity less than a velocity at which the ground vehicle is moving in the forward direction, but sufficient to modify the air flow wake generated by the movement of the ground vehicle in the forward direction.

Abstract: A rear spoiler device (10) for a vehicle (1) has at least one rear door (8, 9), wherein the rear spoiler device (10) has at least one side spoiler (16, 17) with at least one side air guide element (32), which can be moved between a driving position for contour extension and aerodynamic air guidance when the rear door (8, 9) is closed, and a base position when the rear door (8, 9) is open. The side spoiler (16, 17) furthermore has a swing arm (30) with a first pivot joint (31) for pivotable fixation to the rear door (8, 9), the side air guide element (32) is mounted pivotably on the swing arm (30) via at least one second pivot joint (34), and the side air guide element (32) has a locking arrangement on its front end region (32a) for releasable and lockable fixation to the truck (1).

Abstract: There is provided an economical vehicle vibration suppression device capable of efficiently reducing a vortex with a smaller number of devices and controlling the speed of movement in a vehicle longitudinal direction of the vortex. The vehicle vibration suppression device includes a pair of ducts, a pressure control device, and a control unit. The ducts, below a floor surface of a vehicle body, are mounted adjacent to at least a pair of bogies on which the vehicle body is mounted. The ducts are arranged in a direction perpendicular to a traveling direction of the vehicle body and mounted so as to penetrate through both side surfaces of the vehicle body. The pressure control device is mounted within each of the ducts and has openings, one of the openings serving as an intake port and the other opening serving as a discharge port. The pressure control device generates a pressure difference in each of the ducts.

Abstract: There is provided an economical vehicle vibration suppression device capable of efficiently reducing a vortex with a smaller number of devices and controlling the speed of movement in a vehicle longitudinal direction of the vortex. The vehicle vibration suppression device includes a pair of ducts, a pressure control device, and a control unit. The ducts, below a floor surface of a vehicle body, are mounted adjacent to at least a pair of bogies on which the vehicle body is mounted. The ducts are arranged in a direction perpendicular to a traveling direction of the vehicle body and mounted so as to penetrate through both side surfaces of the vehicle body. The pressure control device is mounted within each of the ducts and has openings, one of the openings serving as an intake port and the other opening serving as a discharge port. The pressure control device generates a pressure difference in each of the ducts.

Abstract: A vehicle component includes first and second surfaces, in a first travel direction of the vehicle. The first surface is exposed to an air flow having a local main flow direction. In a region of a recess on the vehicle, the first surface forms a flow separation edge where the air flow is deflected from the first surface. The recess is delimited by a leading first wall facing the local main flow direction and a trailing second wall. The flow separation edge extends transversely to the local main flow direction over a majority of a transverse dimension of the recess. In the local main flow direction, the second surface borders on the flow separation edge and forms a part of the first wall. The second surface is disposed so that it is inclined like a chamfer about an acute angle of inclination relative to the local main flow direction.

Abstract: A transportation system includes a vehicle having wings, a propulsion system, a lifting gear coupling the vehicle to an undercarriage, and a guidance assembly movably connecting the undercarriage to guide rails. The wings generate aerodynamic lift when the vehicle exceeds a first speed. The lifting gear supports a load of the vehicle in a first position in relation to the undercarriage when the vehicle travels at less than the first speed, allows the vehicle to lift to a second position in relation to the undercarriage as the vehicle accelerates beyond the first speed, and maintains the vehicle in the second position when the vehicle exceeds the first speed. The guidance assembly shiftingly engages the guide rails through rollers that are in rolling contact with the guide rails when the vehicle is in the first position and are displaced from the guide rails when the vehicle is in the second position.

Abstract: Disclosed is a series of stacked intermodal containers, being pulled by a locomotive of a train, with aerodynamic drag reducing devices. The series includes at least a first, leading set of containers and a second, trailing set of containers. The first, leading set of containers has an aerodynamic drag reducing device with a drag reducing fairing and an attachment frame attached thereto facing a forward direction. The attachment frame includes at least one mounting device configured to be removably mounted in the tunnel of the top container of the first, leading set of containers. Additionally, the second, trailing set of containers may include a second, aerodynamic drag reducing device, also attached via a gooseneck tunnel. Curtains may also be attached between a plurality of intermediate or adjacent sets of stacked containers to assist in reducing drag on the train when moving.

Abstract: Disclosed is a series of stacked intermodal containers, being pulled by a locomotive of a train, with aerodynamic drag reducing devices. The series includes at least a first, leading set of containers and a second, trailing set of containers. The first, leading set of containers has an aerodynamic drag reducing device with a drag reducing fairing and an attachment frame attached thereto facing a forward direction. The attachment frame includes at least one mounting device configured to be removably mounted in the tunnel of the top container of the first, leading set of containers. Additionally, the second, trailing set of containers may include a second, aerodynamic drag reducing device. Curtains may also be attached between a plurality of intermediate or adjacent sets of stacked containers to assist in reducing drag on the train when moving.

Abstract: A method and apparatus for producing a downward, wind-induced lift force on a structure including attaching one or more omni-directional mushroom-shaped airfoil assemblies to the top of the structure which create a downward lift force as they are subjected to wind flow.

Abstract: A railway vehicle includes an air intake 6 provided at a nose portion of a leading vehicle 1, an air tank (reservoir) 9 for storing intake air, and an air outlet 11, by which air is sucked in (breathed in) during entry of the leading vehicle to a tunnel and discharged within the tunnel, so as to reduce the pressure generated at the nose portion and to cut down micropressure waves. When the nose of the leading vehicle 1 enters a tunnel 3, an intake control valve 8 of the air reservoir, depressurized to below atmospheric pressure (1 atm), opens to take in air through an air inlet 6 via a path 7 into the air reservoir 9. When the whole leading vehicle enters the tunnel, the intake control valve 8 closes, and air is discharged through the outlet 11 via a pump 10.