Exposure to ultrasound energy emitted by remote object detection systems on vehicles is reduced for vehicle occupants. An automotive vehicle has a passenger cabin and a remote sensing system including ultrasonic transceivers mounted for sensing external objects. An ultrasonic microphone is disposed to sense an ultrasonic wave entering the passenger cabin at greater than 30 kHz. An antinoise processor calculates an antinoise signal adapted to at least partially cancel the ultrasonic wave at a predetermined location in the cabin. An amplifier is coupled to the processor for amplifying the antinoise signal by a predetermined gain. An ultrasonic speaker is coupled to the amplifier to project the antinoise signal into the predetermined location to attenuate the ultrasonic wave at the predetermined location.

The control apparatus executes a pulsation compensating control where pulsation compensating torque is calculated for suppressing torque pulsation of an internal combustion engine by a pulsation-compensating-torque calculating portion and an MG1 controlling portion controls a first motor generator to output the pulsation compensating torque, while executes a pressing control where pressing torque is calculated for preventing torque of a second motor generator from crossing 0 Nm by a pressing-torque calculating portion and an MG2 controlling portion controls the second motor generator to output the pressing torque.

A work vehicle includes a cabin to cover an operator's seat on a traveling body. A cabin frame that constitutes a framework of the cabin includes a pair of left and right front pillars, a pair of left and right rear pillars, a front beam, a rear beam, and side beams. The front beam couples upper end portions of the front pillars to each other. The rear beam couples upper end portions of the rear pillars to each other. Each of the side beams couples to each other upper end portions of each of the front pillars and each of the rear pillars that stand at a front and rear. The rear beam is formed to have a U-shaped cross-section by presswork of a metal plate material.

Structure for reducing sloshing noises, said structure being provided for disposal in a liquids container for a motor vehicle, having a random arrangement of mutually interlinked threads, wherein a plurality of the threads at least in portions are connected in a materially integral manner to at least one or a plurality of further threads of the structure, wherein the structure has at least one side in the region of which a planar cover of the random arrangement of mutually interlinked threads is provided at least in portions.

A drive unit of a hybrid vehicle includes an engine; an electric motor; first and second differential mechanisms; a selectable one-way clutch; and a case accommodating the electric motor. Further, the first differential mechanism includes a first rotational element coupled to the electric motor, a second rotational element coupled to the engine, and a third rotational element that outputs power toward drive wheels, the second differential mechanism includes a sun gear coupled to the electric motor, a carrier coupled to the engine, a ring gear whose rotation is regulated by the selectable one-way clutch, and a ring gear flange that rotates integrally with the ring gear, and the selectable one-way clutch switches a state thereof between a locked state and an unlocked state, and the ring gear flange is supported by a rotor shaft of the electric motor via a radial bearing.

An electric vehicle, having a floor assembly of a body structure, the floor assembly including lateral longitudinal carriers, front and rear crossmembers, a vehicle undertray which extends between the lateral longitudinal carriers and the crossmembers and a passenger compartment floor which extends above the vehicle undertray, a technical space between the passenger compartment floor and the vehicle undertray in a rear section of the floor assembly, in which rear section rear seats are mounted above the passenger compartment floor. Furthermore, the electric vehicle includes at least one electric machine and a traction battery arranged below the floor assembly and on the floor assembly. Starting from the passenger compartment floor, the rear crossmember extends as far as into the region of the vehicle undertray and closes the technical space at a rear end. The traction battery is mounted on the lateral longitudinal carriers and on the front and rear crossmembers, and is sealed circumferentially.

A trim structure of a vehicle includes a deck cover constituting a vehicle interior upper portion at a vehicle rear side. The trim structure is provided between a seat and the deck cover and at an upper end of a door main body. The deck cover includes: left and right cover side portions opposed to each other; a rear window opening opening at a vehicle rear side of the seat; and a rear window configured to be openable and closable. The trim structure includes a straightening trim body located between a lower portion of a front end of one of the cover side portions and the seat and projecting to the upper end of the door main body. The straightening trim body is formed so as to straighten traveling wind to the rear window opening in an open state, the traveling wind flowing into a vehicle interior.

A method of making a polymeric engine hood assembly for use in a vehicle can include applying heat to a first polymeric sheet, applying heat to a second polymeric sheet, stacking the first polymeric sheet and the second polymeric sheet, placing the stacked sheets between a first mold half and a second mold half, closing the first mold half and second mold half, applying vacuum to the space between the first polymeric sheet and the first mold half and between the second polymeric sheet and the second mold half, wherein the first polymeric sheet forms an exterior panel and wherein the second polymeric sheet forms a reinforcing structure; and attaching an exterior panel to a fender skin at a junction surface, wherein the reinforcing structure includes a connecting ridge extending transversely across the reinforcing structure, wherein the connecting ridge is configured to accept the junction surface of the exterior panel and the feeder skin.

An air-conditioning register includes a retainer, a downstream fin, a knob, an upstream fin, and a fork. The downstream fin is swingably supported by the retainer with a downstream fin pivot. The knob is slidably attached to the downstream fin. The upstream fin has a transmission shaft. The fork is pivotally supported by the knob and includes two fork pivots. The knob includes two pivot receiving portions each having a pivot receiving hole. Each fork pivot is inserted into the pivot receiving hole of the corresponding one of the pivot receiving portions. An overlapping portion is provided at least at part of a location at which the fork and each pivot receiving portion contact each other. Slits are provided at two locations between the two fork pivots of the fork. A region between each slit and the nearest fork pivot constitutes an elastic support portion.

A device and a method for operating a multi-axle drive train for a motor vehicle. A first axle and a second axle are operatively connected, at least temporarily, to a drive device. When the second axle is decoupled from the drive device and a request for multi-axle drive with a first value is present, the second axle is coupled to the drive device only when a noise-masking event occurs, or when the second axle is coupled to the drive device and the request for multi-axle drive is absent, the second axle is decoupled from the drive device only when the noise-masking event occurs.