An active outside rear view system for a vehicle includes a support structure mounted to an exterior surface of the vehicle. A rear view device is movably affixed to the support structure. A linkage extends from a first end to a second end, where the first end of the linkage is movably affixed to an aerodynamic enclosure and the second end of the linkage is movably affixed to the support structure. An actuator is engaged with the linkage and moves the aerodynamic enclosure between at least a first position and a second position different from the first position. The aerodynamic enclosure is independently movable relative to the rear view device and the support structure. The aerodynamic first position and the second position provide differing aerodynamic characteristics to the active outside rear view system.

A motor vehicle with an automatically adjustable front wing and with an automatically adjustable rear wing, which are each adjustable in a controlled manner by an actuator. The motor vehicle has a front axle with front wheels and a rear axle with rear wheels. By way of the adjustment of the front wing and/or the rear wing, a downforce is caused on the front axle due to the inflow of air onto the front axle, and a downforce on the rear axle is caused due to the inflow of air onto the rear axle. A resulting downforce passing through a point can be produced, and an aero balance can be adjusted. The downforce on the front axle, the downforce on the rear axle, the resulting downforce, and/or the aero balance can be controlled and/or adjusted automatically and/or manually.

A motor vehicle with an automatically settable front wing and an automatically settable rear wing, each of which is settable under the control of an actuator. Owing to the incident flow of air at the front axle, a downforce at the front axle (FDF) can be set by positioning the front wing. Owing to the incident flow of air at the rear axle, a downforce at the rear axle (RDF) can be set by positioning the rear wing. A resultant downforce (DF) acting through a point (CoP) can be generated and an aero balance (AB) can be set. The rear wing and/or the front wing can be set automatically in dependence on an operating state of the motor vehicle such that a predetermined downforce (FDF) at the front axle, a predetermined downforce (RDF) at the rear axle, a predetermined resultant downforce (DF) and/or a predetermined aero balance (AB) is obtained.

An adapter panel for establishing a horizontal return and optional mount for accessories to a vehicle without a horizontal return. The adapter panel substantially conforming to a portion of a vehicle. The adapter panel solidly mounted to the underside of a vehicle, forming a surface upon which accessories can be mounted, or, alternatively having a lower surface having a reduced surface area in order to limit force applied to the panel and the vehicle. The panel further having an edge portion disposed along a perimeter, between the upper and lower surface, optionally securing the panel to the vehicle and deflecting obstacles, and one or more mounting points for removably attaching the protection panel to a portion of the exterior of a vehicle.

A vehicle accessory includes a body portion. The body portion is made substantially of aluminum composite material. The vehicle accessory further includes at least one connector for selectively attaching the body portion to a portion of an automobile. The body portion includes a front edge and a rear edge. The front edge is curved along at least a portion thereof. The front and rear edges are laterally opposed from each other. The rear edge extends substantially linearly from a first corner to a second corner. The first and second corners are formed at junctions between the front edge and the rear edge.

A system and method for controlling deployment of a vehicle air dam that include receiving vehicle data associated with a vehicle operating condition. The system and method also include analyzing the vehicle data to determine if an elevated engine load condition is present to implement a normal air dam deployment mode or a prohibitive air dam deployment mode. The system and method further include controlling an actuator associated with the vehicle air dam to deploy or retract the vehicle air dam based on the implementation of the normal air dam deployment mode or the prohibitive air dam deployment mode.

An active air flap device for a vehicle may include: a housing part mounted in a bumper cover part; one or more flap parts rotatably mounted in the housing part, and exposed to the outside through a hole formed in the bumper cover part to form the same skin line as the bumper cover part; a link part connected to the flap part; a loader part mounted in the link part; and a driving part configured to rotate the loader part.

Various embodiments are directed to an air jet shield. The air jet shield may include a support frame configured to attach to a vehicle utilizing a set of security straps. Sets of V-shaped and concave air ducts may be horizontally and vertically coupled to the support frame, respectively. Each of the air ducts may have a decreasing cross-sectional area and include (i) an inlet that receives air from a surrounding environment during a travel of the vehicle into a headwind or crosswind and (ii) an outlet that dispenses the air received from the inlet as a free air jet. Upon entering a headwind or crosswind, the free air jet creates a wind shear causing rotation at an increased velocity. Within the free air jet and surrounding the vehicle, static air pressure and wind velocity is decreased, thereby causing a reduction in aerodynamic drag during travel.

An airflow adjusting apparatus to be provided in a vehicle includes a flap and an airflow generator. The vehicle includes a wheel disposed to be partly protruded downward from a vehicle body of the vehicle. The flap is protruded, in front of the wheel, downward from the vehicle body. The airflow generator is provided in an underneath of the vehicle body and vehicle-widthwise inwardly from the wheel. The airflow generator is configured to generate an airflow vehicle-widthwise inward, and backward of the vehicle. The airflow moves obliquely relative to a vehicle longitudinal direction when the vehicle travels forward.

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.