A vehicle includes a rear lamp, a side surface, and a rear surface. The rear lamp is disposed on a rear end and an upper end of a lower side surface and a rear end and a side end of the vehicle, and includes a lamp body extending in a front-rear direction of the vehicle. The side surface includes the lower side surface bulging toward a vehicle-width-direction outer side with respect to the rear lamp at a front side of a height position overlapping with the rear lamp. The rear surface includes an extending surface extending toward the vehicle-width-direction outer side with respect to the lamp body in a top view of the vehicle from a lower portion of the lamp body. A side surface airflow is directed toward a vehicle-width-direction inner side through the extending surface and the generation of a large trailing vortex is suppressed.

An active spoiler for a vehicle including a fixed portion configured for attachment to the vehicle, an extendable portion configured for movement relative to the fixed portion, and a flexible portion secured between the fixed portion and the extendable portion. The spoiler has a retracted configuration and an extended configuration, whereby the flexible portion is stowed within the spoiler in the retracted configuration and the flexible portion is deployed in the extended configuration.

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 removable spoiler or vehicle stabilizing apparatus for a pickup truck having a truck bed is provided. The spoiler comprises a spoiler shell constructed and arranged to fit securely on the truck bed, an interior spoiler frame, at least one mounting support configured to securely support the spoiler on the truck bed, and a plurality of spoiler securement and lifting elements. The spoiler may easily be installed or removed from the truck even while the truck is hitched to a travel trailer, camper trailer or the like. The spoiler may be installed or removed with any suitable device, such as a crane, jack, jack stands, cherry picker, auto cherry picker, travel trailer tongue-mounted lift/crane, lifts, roll on/off platform or the like. The spoiler may also be used as a multipurpose device, and may provide a golf cart enclosure, and may further comprise at least one utility shelf.

A method for operating an air guiding device of a motor vehicle includes adjusting an air guiding element of the air guiding device from a starting position into an active position which influences aerodynamics of the motor vehicle. The method further includes exerting feedback pertaining to the adjusting of the air guiding element on a motor vehicle occupant in a form of a relative movement acting on the motor vehicle occupant, where the relative movement is generated by an adjustment of a chassis and/or a seat system of the motor vehicle from a first position to a second position.

An airflow adjusting apparatus includes two or more airflow generators and a controller. The airflow generators are arranged in first and second directions along a surface of an object. The airflow generators are configured to generate respective airflows in parallel directions parallel along the surface of the object. The second direction intersects with the first direction. The controller is configured to control outputs from the respective airflow generators independently of each other. The controller is configured to cause a total output from the airflow generators in a first group to be greater than a total output of the airflow generators in a second group. The airflow generators in the first and the second groups are arranged side by side in an airflow generation direction. The airflow generators in the second group are adjacent to those in the first group.

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.

Disclosed is a high-integration-level plastic tail door, comprising a tail door upper outer plate, a tail light, a tail door lower outer plate, an inner plate, and a high brake light, wherein the tail door upper outer plate, as a whole, is integrated with a spoiler, a tail door windshield, a windscreen decorating member, and a high brake light cover; the tail door upper outer plate is of two layers and is formed by means of double-shot molding, with a first layer being a transparent layer and a second layer being a black non-transparent layer; a first open hole is provided at the position of the high brake light in a black non-transparent layer area; a second open hole is provided in the middle of the tail door windshield; and a hardened coating is arranged on the outer layer of the transparent layer.

The invention relates to a flow guiding apparatus of a motor vehicle, comprising a spoiler which is fastened to a tailgate of the motor vehicle, and to an adjustment kinematics device for adjusting the spoiler between a rest position, in which the spoiler is arranged in a flush-mounted manner in the tailgate, and at least one functional position, in which the spoiler is deployed beyond the vehicle contour or the surface of the tailgate with regard to the height and/or the angle. In order to achieve a downforce effect and/or braking effect and/or aerodynamic improvement during driving of the motor vehicle, the adjustment of the adjustment kinematics device takes place via actuable drive means. This flow guiding apparatus is intended to be developed in such a way that a multiplicity of operating positions of the spoiler can be set with a compact overall design and integration into the movable tailgate, with at least one operating position intended to fulfil the function of an air brake. For this purpose, the adjustment kinematics arrangement comprises at least one adjustment kinematics unit which is formed from a first adjustment kinematics system and a second adjustment kinematics system which is coupled to the former in an operatively connected manner, the first adjustment kinematics system being configured as a four-bar linkage and to set a deployment height, and the second adjustment kinematics system being configured as a four-bar linkage and to set a deployment angle, and an adjustment of the spoiler being a superimposed kinematic adjustment movement of the first and second adjustment kinematics system, and the first adjustment kinematics system comprising at least one pivoting axle which is mounted in a stationary manner and is pivotal via an electric motor as drive means, and the second adjustment kinematics system comprising a pivoting axle which is mounted in a stationary manner and is pivotable via a separately actuable electric motor as drive means.

An air guiding element, in particular a cooling air louver for an air inlet of a motor vehicle body, with a flat main body and with a bearing region. The air guiding element is arranged such that it can be pivoted by way of its bearing region about a pivot axis. The flat main body is formed from two shells, and with a carrier element which is arranged between the shells. The carrier element is molded between the two shells by an injection molding method such that the two shells are connected to one another in this way.