An occupant protection device for a vehicle includes a collision predictor, a main airbag, a seat, a sub-airbag, and a deployment controller. The collision predictor is configured to predict a collision of the vehicle. The main airbag is configured to deploy toward an occupant from a front of the vehicle when a collision of the vehicle is predicted by the collision predictor. The seat allows the occupant to be seated, and is movable in a front-back direction of the vehicle. The sub-airbag is accommodated in an upper part of the seat, and configured to deploy downward from above the occupant. The deployment controller is configured to, when a collision of the vehicle is predicted by the collision predictor, cause the sub-airbag to deploy from the upper part of the seat and subsequently cause the main airbag to deploy.

An airbag device of the disclosure includes an airbag module that is installed in a central region of a steering wheel of a vehicle, and that accommodates an airbag that can deploy behind the steering wheel when a driver is seated in the driver's seat. The airbag module has an airbag inflation control unit that controls an inflation direction of the airbag in such a manner as to allow the airbag to inflate above the airbag module, after the airbag has inflated in such a direction as to abut on the driver's chest at the time of deployment of the airbag.

An assembly includes a seatback and an airbag. The airbag includes an upper panel and a lower panel spaced from each other and an intermediate panel disposed therebetween. The upper panel and the lower panel are each uninflatable and each supported by the seatback. The intermediate panel is supported by the seatback and inflatable to an inflated position. The intermediate panel in the inflated position includes a valley elongated in a direction from the lower panel towards the upper panel.

The present invention relates to a system that is mounted on a mounting structure or chassis intended to protect the vehicles and their occupants. The system uses a main computer, high-precision radars, external airbag impellers, airbags that protect the vehicle and to some extent help its buoyancy, fluid sensors to detect the water limit that the vehicle can reach, and if these sensors are activated send a signal to the main computer that is responsible for activating air bag impellers, an inclinometer to detect the limit of inclination established in the vehicle and if the inclinometer detects an inclination that exceeds the limit established, this sends a signal to the main computer that is responsible for activating all the air bag impeller devices; and a monitor with signal transmitters to visualize in the state in which the system is located.

An occupant protection device includes a pair of first and second lap belt guiding surfaces, a pair of first and second shoulder belt guiding surfaces, a pair of first and second thigh belt guiding surfaces and a connector. A pair of left and right lap belts, are withdrawable from the pair of first and second lap belt guiding surfaces to restrain a waist of a seated occupant. A pair of left and right shoulder belts are withdrawable from the pair of first and second shoulder belt guiding surfaces to restrain an upper body of the seated occupant. A pair of left and right thigh belts are withdrawable from the pair of first and second thigh belt guiding surfaces to restrain thighs of the seated occupant, wherein the pair of lap belts, the pair of shoulder belts and the pair of thigh belts are connected to the connector.

In various examples, systems and methods are disclosed that accurately identify driver and passenger in-cabin activities that may indicate a biomechanical distraction that prevents a driver from being fully engaged in driving a vehicle. In particular, image data representative of an image of an occupant of a vehicle may be applied to one or more deep neural networks (DNNs). Using the DNNs, data indicative of key point locations corresponding to the occupant may be computed, a shape and/or a volume corresponding to the occupant may be reconstructed, a position and size of the occupant may be estimated, hand gesture activities may be classified, and/or body postures or poses may be classified. These determinations may be used to determine operations or settings for the vehicle to increase not only the safety of the occupants, but also of surrounding motorists, bicyclists, and pedestrians.

In various examples, systems and methods are disclosed that accurately identify driver and passenger in-cabin activities that may indicate a biomechanical distraction that prevents a driver from being fully engaged in driving a vehicle. In particular, image data representative of an image of an occupant of a vehicle may be applied to one or more deep neural networks (DNNs). Using the DNNs, data indicative of key point locations corresponding to the occupant may be computed, a shape and/or a volume corresponding to the occupant may be reconstructed, a position and size of the occupant may be estimated, hand gesture activities may be classified, and/or body postures or poses may be classified. These determinations may be used to determine operations or settings for the vehicle to increase not only the safety of the occupants, but also of surrounding motorists, bicyclists, and pedestrians.

A passenger protection apparatus for vehicle includes an airbag, a tether, a tension member, and a controller. The airbag is configured to deploy via a seat on which a passenger sits or a periphery member of the seat. The tether has a first end coupled to a front portion of the airbag in a deployment direction of the airbag. The tension member is coupled to a second end of the tether and configured to pull the first end to the seat side. The controller is configured to activate the tension member to pull the tether at the same time as the airbag deploys, when the airbag is deploying, or after the airbag has deployed.

A gas distribution system for airbag inflation in a vehicle can include: a passenger airbag including a plurality of inflatable chambers; an airbag inflation device configured to produce a gas when a collision involving the vehicle is sensed and to supply the gas to the passenger airbag, causing deployment of the passenger airbag; and an inflation gas distributor disposed at least partially between the airbag inflation device and the passenger airbag, the inflation gas distributor including a rotatable distributor belt, the inflation gas distributor configured to allow passage of the gas from the airbag inflation device to a first subset of the plurality of chambers, and to impede passage of the gas from the airbag inflation device to a second subset of the plurality of chambers, by rotating the distributor belt to a gas distribution position selected among a plurality of predetermined gas distribution positions.

A restraint system for a vehicle includes an instrument panel and an airbag supported by the instrument panel. The restraint system includes a right deflector supported by the instrument panel adjacent the airbag. The right deflector is deployable between a retracted position and a deployed position. The restraint system includes a left deflector supported by the instrument panel adjacent the airbag opposite the right deflector in a cross-vehicle direction. The left deflector is deployable between a retracted position and a deployed position. The restraint system includes a first pyrotechnic device coupled to the right deflector and a second pyrotechnic device coupled to the left deflector.