A vehicle comprising: a passenger compartment; a nose region forwards of the passenger compartment, the nose region having a top surface and a front; and a duct running from an inlet to an outlet to permit air flowing into the inlet to be channeled to the outlet, the inlet being positioned at the front of the nose region below the top surface and the outlet being positioned on the top surface of the nose region behind the inlet, the outlet being oriented so that air flowing through the outlet is directed in an upwards direction, the upwards airflow causing disruption to a rearward airflow moving towards the passenger compartment.

An aerodynamic fairing assembly for attachment to a trailer of a tractor-trailer. The aerodynamic fairing assembly may comprise a front skirt fairing and a rear skirt comprising a transition. The transition may extend outwardly of the side skirt fairing at a distance from the centerline of the trailer. The side skirt faring and rear skirt fairing are coupled to the trailer by one or more struts.

Systems and methods are provided for generating a downforce on a vehicle. An aerodynamic deflector on the vehicle is repositionable. An actuator is coupled with the aerodynamic deflector. A controller configured to: detect a performance mode of operation of the vehicle; determine a requested lateral acceleration; calculate a control adjustment of the aerodynamic deflector to generate a downforce to achieve the requested lateral acceleration and maximize lateral grip of the vehicle; and operate the actuator to effect the control adjustment of the aerodynamic deflector to generate the downforce on the vehicle.

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.

An active air dam assembly includes, among other things, an air dam configured to pivot relative to a vehicle bumper back and forth between a home position and a deflected position and an actuator system configured to transition the air dam vertically between a raised position and a deployed position.

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 vehicle including an embossed surface for improving aerodynamic characteristics includes a front bumper member provided at a lower portion of a front surface of a vehicle body of the vehicle. On a surface of a side surface portion of the front bumper member, the embossed surface having a directional pattern for assisting an airflow to direct in one direction along the surface is formed. The one direction is raised rearward relative to a front-rear direction of the vehicle body.

A vehicle front structure is provided for preventing a vortex from being generated between high-speed air separated from an outer edge of a deflector and low-speed air in a front wheel house due to a wind speed difference. Embodiments include a deflector disposed in front of a front wheel house projected downward from a lower surface of a bumper face. The deflector includes an air introducing section to introduce air into a space inside the deflector in a front portion of the deflector; and an intermediate-speed wind generating hole section that communicates with the air introducing section and generates an airflow at an intermediate wind speed, lower than a wind speed of air separated from deflector outer edges and higher than a wind speed of air in the front wheel house, in an area not opposing a tire in a vehicle front view of a portion immediately behind the deflector.

An apparatus, according to an exemplary embodiment includes, among other things, a single-piece bracket having a first mount interface configured to receive a fog lamp and a second mount interface configured to receive an actuator for an active air dam. A method according to an exemplary aspect of the present disclosure includes, among other things, injection molding a single-piece bracket from a plastic material to include a first mount interface configured to receive a fog lamp and a second mount interface configured to receive an actuator for an active air dam.

A structure improvement of automobile spoiler, comprising a midsection, a right section and a left section; its features are: the spoiler of the present invention can be separated into a midsection, a right section and a left section, various parts and components can be buckled up to form one piece, after buckle combination, the parts are fastened by wood screws to form an integrated spoiler, when it is broken by collision, only the broken part is changed, the replacement cost is reduced, and the present invention can be split up, the size of the box for loading the present invention is reduced, more convenient for transportation, and the box cost is reduced.