An airflow deflector for a vehicle protrudes downward from an inner fender having a wheel housing that houses a front wheel. The airflow deflector includes an airflow guide member extending in both a lateral direction and a vertical direction of the vehicle and provided in front of the wheel housing. The guide member has an inboard end portion and an outboard end portion. The inboard end portion is spaced inboard from an inner sidewall of the front wheel and the outboard end portion is spaced inboard from an outer sidewall of the front wheel. The outboard end portion includes a cutout to guide airflow around the outer sidewall of the front wheel.

Disclosed is an air supply system for a whole vehicle, which is intended to solve the technical problem that it is hard to provide a multi-position and controllable air supply solution for an electric vehicle. A first air source device, a control valve and a pipeline constitute a first-type air supply system, the first-type air supply system has multiple air passages, each air passage is respectively provided with an air supply port, and a controller can switch operating states of the control valve, control the opening or closing of the multiple air passages, and achieve controllable air supply effects in multiple positions. A second air source device and several pipelines constitute a second type of air supply system, the second type of air supply system has multiple air passages, each air passage is respectively provided with an air supply port, and a controller can switch operating states of the second air source device, control the opening or closing of the multiple air passages, and achieve controllable air supply effects. The first type of air supply system and the second type of air supply system are rationally configured on the electric vehicle, so as to achieve multi-position and controllable air supply effects.

Disclosed is an air supply system for a whole vehicle, which is intended to solve the technical problem that it is hard to provide a multi-position and controllable air supply solution for an electric vehicle. A first air source device, a control valve and a pipeline constitute a first-type air supply system, the first-type air supply system has multiple air passages, each air passage is respectively provided with an air supply port, and a controller can switch operating states of the control valve, control the opening or closing of the multiple air passages, and achieve controllable air supply effects in multiple positions. A second air source device and several pipelines constitute a second type of air supply system, the second type of air supply system has multiple air passages, each air passage is respectively provided with an air supply port, and a controller can switch operating states of the second air source device, control the opening or closing of the multiple air passages, and achieve controllable air supply effects. The first type of air supply system and the second type of air supply system are rationally configured on the electric vehicle, so as to achieve multi-position and controllable air supply effects.

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 aerodynamic system for a truck (12) is provided that has a faring (14) carried by the truck with an outer surface (24) that is an air flow surface across which air flows when the truck is moving forward. The faring has a tailing end with a first kick out (22) that has a first kick out exit surface (24) oriented at a first angle with respect to the air flow surface. The tailing end has a second kick out (28) with a second kick out exit surface (30) oriented at a second angle with respect to the air flow surface. The first angle is different than the second angle. The truck has a longitudinal axis, a longitudinal direction and a vertical direction. The air flow surface is located forward from the tailing end in the longitudinal direction, and the first kick out is located higher than the second kick out in the vertical direction.

A system for reducing drag on a trailer includes a flexible membrane including a perimeter coupled to a rear end of the trailer. A variable-volume cavity is defined between the flexible membrane and the rear end. The system also includes a source of pressurized gas coupled to the trailer and in fluidic communication with the variable-volume cavity, and a controller operable to control a flow of the pressurized gas from the source to the variable-volume cavity such that the flexible membrane is moved from a stowed profile, wherein the flexible membrane is collapsed against the rear end of the trailer, to a first deployed profile, wherein the flexible membrane is maintained in a first pre-selected tapered aerodynamic shape projecting rearward from the rear end.

An elongated pillar garnish configured to be attached to a gap between a peripheral edge portion of a window pane of a vehicle and a pillar of the vehicle, the pillar garnish including: an elongated attachment member for attaching the pillar garnish to the gap; and an elongated decorative member assembled to a front surface side of the attachment member, in which the attachment member includes an elongated main body part, and a cover part provided to at least one end of the main body part in a longitudinal direction, in which the cover part has a covering portion covering at least a part of a front surface of the decorative member, and a supporting wall portion erected from the main body part toward the outer side and supporting the covering portion, and in which the supporting wall portion is provided along a direction intersecting with the longitudinal direction.

A cargo area structure has a retractable step installed to the cargo area structure beneath a floor and a first side wall thereof. A handle assembly has a base and a grip handle supported to the base. The base is attached to an upright surface of the first side wall. The base also has a position locking mechanism configured such that in response to manual operation of the position locking mechanism, the grip handle is movable from a stowed orientation and an in-use orientation such that in the in-use orientation the grip handle is positioned such that an individual using the step to enter the cargo area grabs the grip handle for assistance in stepping up into the cargo area.

An active side panel assembly having at least one deployable panel (22) and at least one actuator (30). The deployable panel deploys and retracts based on vehicle requirements and provides valueable reduction in vehicle drag, thereby reducing emissions and improving fuel economy. Additionally, it allows for the system to retract so the vehicle can still meet ground clearances, ramp angles, off-road requirements, etc. The active side panel provides a fully deployable system with object detection, declutching of the actuator to help prevent damage, and communication with the vehicle to determine proper deployment and function.

A vehicle includes a heat exchanging type cooling device includes an undercover disposed below the cooler body and having an air exhaust passage into which the ambient air discharged through the lower surface of the cooler body is introduced and through which the ambient air is exhausted into outside atmosphere, under a negative air pressure generated due to an air stream generated during running of the vehicle; and an elastically deformable sealing member in a closed form interposed between the air exhaust passage and the lower surface of the cooler body. The undercover is attached to the body of the vehicle, such that a gap is provided between the undercover and the lower surface of the cooler body, and such that the sealing member fluid-tightly closes the gap.