An automobile comprising a cooling duct that extends to underneath the automobile to channel cooling air to a component of the automobile when the automobile is in motion is provided. A restriction located within the cooling duct that is moveable from a first position, in which airflow to the component is substantially unimpeded, to a second position in which the airflow to the component is substantially impeded, when the automobile is in motion is further provided. The automobile generates more downforce when the restriction is in the second position versus the first position. A control unit configured to select the position of the restriction to control the downforce generated by the automobile if the temperature of the component is below a predetermined level, and to select the first position for the restriction if the temperature of the component is above the predetermined level, is also provided.

A rear spoiler device (8) for a vehicle comprises an air-guiding element (9, 19), which can be moved between a retracted base position and a driving position and has a guiding surface (9d) for aerodynamically extending the contour of an exterior surface (4, 3) of the vehicle in the driving position. The air-guiding element (9) has a contact edge (9c) extending in a lateral direction (y) for contacting the exterior surface (4) of the vehicle (1) in the driving position, wherein the rear spoiler device (8) can be mounted completely on a rear door of the vehicle, the air-guiding element (9, 19) being designed in a multi-layer manner.

A motor vehicle includes a body having a front apron, and an underbody. The body forms at least one left and one right front wheel house for receiving one front wheel each. The air-guiding devices have at least one left flow duct and at least one right flow duct. The at least one left flow duct opens in the underbody in front of the left wheel house. The at least one right flow duct opens in the underbody in front of the right wheel house. The respective exit opening is arranged in front of that region of the respective wheel house which is adjacent to the inner side, which faces the vehicle central plane, of the respective vehicle wheel in the straight-ahead position.

Provided is an assist grip handle storing an escape hammer. The handle is to be attached to an interior space of a vehicle, and includes a bar-shaped grip portion; a curved portion continuous with at least one end of the grip portion; and an attachment portion continuous with the curved portion and attached to an interior member of the vehicle. Since provided inside the grip portion is a storage portion continuous with an opening section formed at the curved portion side, and an escape hammer is stored in the storage portion, the hammer can be stored in the handle in a compact manner. Since there are provided a biasing member biasing the hammer toward the opening section side; a regulation portion for regulating the hammer; and a push button for releasing the restriction by the regulation portion, the hammer can be easily installed in and removed from the handle.

A plastic glazing of a tailgate of a vehicle is provided, the plastic glazing comprising: a first translucent component comprising a full panel of the plastic glazing; a second translucent component molded onto the first translucent component, wherein the second translucent component is a colored thermoplastic polymer, wherein the plastic glazing is of one-piece molded plastic construction, wherein at least one of the first translucent component and the second translucent component comprises one or more aerodynamic features, wherein the one or more aerodynamic features are each configured to reduce one or more of: a turbulence, a drag force, and a lift force.

The present invention is predicated upon the provision of systems and methods for reinforcement of a structural member. More particularly, the present invention is predicated upon unique carrier configurations and application of reinforcing material thereto. In one configuration, the application of reinforcing material is achieved without the use of fasteners, adhesives, or both, for placement, locating and restrictive movement of the reinforcing material onto the carrier.

An air-conditioning control apparatus for a vehicle capable of unmanned driving includes a determining section that is configured to determine whether an occupant is in the vehicle and an output section that is configured to execute an air-conditioning control based on a determination result by the determining section. The output section is configured to execute the air-conditioning control based on ride schedule information indicating a length of time until an occupant rides in the vehicle when the vehicle is determined to be in an unmanned state.

An air-conditioning control ECU is an air-conditioning control apparatus mounted in an automated driving vehicle, and includes an occupant determining section that determines whether an occupant is in the automated driving vehicle, and a window operation controlling section that executes a window operation air-conditioning control for performing cabin air-conditioning when a determination result of the occupant determining section indicates the automated driving vehicle is in an unmanned traveling state.

There is provided a door hatch assembly for an aperture in a screen door, the assembly including a substantially round rim mountable on a periphery of the aperture; a static member mounted in the rim and configured to cover at least a first portion of the aperture; and a hatch engaged with the static member and movable over the static member to reversibly cover at least a second portion of the aperture.

There is provided a door hatch assembly for an aperture in a screen door, the assembly including a substantially round rim mountable on a periphery of the aperture; a static member mounted in the rim and configured to cover at least a first portion of the aperture; and a hatch engaged with the static member and movable over the static member to reversibly cover at least a second portion of the aperture.