The present invention concerns a position-variable motorized vehicle aerodynamics module (12), comprising: A flow component (14) which is configured to be subjected to an incident flow or surrounding flow of an airstream (F), A bracket (22), which is configured for fixed attachment to a structure (20) fixed to a vehicle, A power unit (28), which is configured to displace the flow component (14) between at least two different operating positions relative to the bracket (22) under normal operating conditions, A connecting structure (36), which the flow component (14) connects with the power unit (28) in a force- and movement-transmitting manner, and A guiding arrangement (26), which guides the displacement movement of the flow component (14) between the at least two operating positions,

Where the connecting structure (36) is configured, in the event of a force being transmitted to the flow component (14) through collision with a solid body (42), to allow through deformation an evasive movement of the flow component (14) relative to the bracket (22).

According to the invention it is provided that the connecting structure (36) is part of the guiding arrangement (26), where the evasive movement differs from the displacement under normal operating conditions.

An active air dam notification method includes, among other things, transitioning an air dam of a vehicle between a first position and a second position, and providing an alert to a user. The alert indicates that the air dam is transitioning. The air dam is vertically higher when the air dam is in the first position than when the air dam is in the second position

A motor vehicle having a first portion and a second portion movable relative thereto; the vehicle further includes an actuator arrangement by which the second portion is drivable relative to the first portion; and the vehicle having a control apparatus that is coupled to the actuator arrangement and controls the operation of the actuator arrangement; the actuator arrangement including at least two separate actuators arranged remotely from one another, which are each switchable between an operating state wherein an output member of the actuator outputs a force and/or a motion, and a passive state in which the output member does not, the actuators are synchronously operable in a synchronous operating mode, wherein one actuator, constituting a master actuator, is coupled directly to the control apparatus, and the at least one further actuator is connected to the energy supply of the master actuator only such that the at least one further actuator is supplied with operating energy, and is in the operating state, only when the master actuator is switched by the control apparatus into the operating state.

In a deflector device, a magnet is rotated when a deflector body is rotated, and a magnetic sensor also detects a rotational position of the magnet. Moreover, an interior of a housing body is partitioned by a motor base into a vehicle width direction outside of the interior and a vehicle width direction inside of the interior, with the magnet housed on the vehicle width direction outside of the interior of the housing body. The magnetic sensor is housed on the vehicle width direction inside of the interior of the housing body. This accordingly enables foreign matter ingression from the vehicle width direction outside of the interior of the housing body into the vehicle width direction inside thereof to be suppressed by the motor base, enabling foreign matter to be suppressed from reaching the magnetic sensor.

In a deflector device, a deflector body is rotated with respect to a case. A restriction plate of the case covers a divide between the deflector body and the case. Foreign matter is accordingly suppressed from ingression between the deflector body and the case by the restriction plate.

An air guide apparatus for a vehicle includes a front wheel housing at least partially surrounding a front wheel, and having an air outlet which is open to the front wheel, a first vane assembly including a plurality of first vanes which are tiltable in a position adjacent to the air outlet, and a first driving mechanism by which the plurality of first vanes are driven, and a second vane assembly including a plurality of second vanes which are tiltable in a position adjacent to the plurality of first vanes, and a second driving mechanism by which the plurality of second vanes are driven.

A vehicle front structure for a vehicle including a front exterior member provided on a front surface of a vehicle body includes a front introduction hole and a duct structure. The front introduction hole is formed in an end portion of the front exterior member in a vehicle width direction. The duct structure is coupled to the front introduction hole inside the front exterior member. The duct structure includes a rear exhaust hole that exhausts air to a wheel house located at a rear side of the front exterior member in the vehicle body, and a branch exhaust hole formed in a flow path section provided between the front introduction hole and the rear exhaust hole.

A method and an apparatus, according to an exemplary aspect of the present disclosure includes, among other things, a fascia having a first fascia portion that is selectively moveable relative to a second fascia portion, and an engine shield that has at least a first shield panel and a second shield panel. The first shield panel has a first portion that moves with the first fascia portion and a second portion that is connected to a vehicle static structure. The second shield panel is mounted for movement with the first fascia portion. At least one actuator selectively moves the first fascia portion relative to the second fascia portion in response to at least one predetermined vehicle input condition.

Disclosed herein are embodiments of a vehicle body shield having a light mount. The vehicle body shield can protect portions of a vehicle from damage when the vehicle is in motion and also provide illumination to regions around or in front of a vehicle via light sources supported by the light mount. The vehicle body shield can have a protection surface facing away from the vehicle, an attachment surface facing towards the vehicle, and a light mount extending upward from at least a portion of the attachment surface and between first and second ends of the vehicle body shield.

An airflow deflector for a vehicle includes: an exterior surface and at least one airflow deflector area in a portion on a vehicle rear side of the exterior surface. The airflow deflector area includes a slanted side that is slanted in a manner to extend to a vehicle lower side as extending to the vehicle rear side and an airflow deflector surface that extends in a vehicle vertical direction from the slanted section toward the exterior surface. An extending direction of a side of the airflow deflector surface, which serves as a boundary between the airflow deflector surface and a surface of the cover, is oriented inward or outward in a vehicle width direction with respect to a vehicle longitudinal direction. The airflow deflector surface is tilted inward or outward in the vehicle width direction with respect to the surface of the cover.