A system and method are provided for controlling an interior configuration of a vehicle. The system may include an interior vehicle component, an actuator component configured to adjust a physical configuration of the interior vehicle component, an external communication component configured to collect driving environment data representing an external environment of the vehicle, and one or more processors configured to receive driving environment data and detect, by processing the driving environment data, an external driving condition. When the one or more processors detect the external driving condition, the one or more processors may cause the actuator component to adjust the interior vehicle component from a first physical configuration to a second physical configuration, or may cause the actuator component to restrict movement of the interior vehicle component to a predetermined range of physical configurations.

Occupant safety systems suitable for use in both traditional and opposed seating systems include various combinations of passive safety components: sensors that provides an output signal indicative of an imminent collision, seats selectively moveable relative to seat support structures in response to the output signal, inflatable restraints deployable from lap portions of a tensioned restraint based on the output signal, airbags deployable from a roof of a vehicle based on the output signal, cabin dividers deployable from a side of a cabin of the vehicle or the roof of the vehicle based on the output signal, and curtain airbags deployable between an occupant and the side of the cabin of the vehicle based on the output signal.

A passenger protection apparatus for a vehicle includes first and second airbags, an airbag deployment device, a collision speed detector, a passenger's position detector, a seat moving unit, an airbag deployment determination unit, and a deployment controller. The first airbag is deployable in different sizes. The second airbag is deployable between the first airbag and vehicle equipment. The airbag deployment device deploys the airbags. The collision speed detector detects a collision or collision possibility of a vehicle, and calculates a collision speed. The passenger position detector detects a position of a passenger sitting on a seat. The seat moving unit moves the seat. The airbag deployment determination unit determines a size of the deployed first airbag. The deployment controller determines an amount of movement of the seat, causes the seat moving unit to move the seat, and causes the airbag deployment device to deploy the airbags.

An arrangement in passenger vehicles, that diverts the impact energy in lateral or side impacts away from the passengers to the remaining mass of the vehicle thereby protecting the passengers, and in the same arrangement provides utilitarian access to the vehicle, such utilitarian access making it possible to both install multi-element contoured surround seats for passengers and the driver, and also a safety device for head-on collision protection that obviates the need for conventional seat belts and front impact airbags. An indo-skeletal structural arrangement proposed for the vehicle, provides further benefits by targeting the strength of the vehicle to protect passengers while minimizing other massive elements in the vehicle. Side impact protection for the head and neck are proposed with airbags and aircushions.

A vehicle seat arrangement has a vehicle seat for attaching to a vehicle structure of a vehicle, in particular a motor vehicle, with a lower seat part having a seat structure and with a seat back. The lower seat part is mounted or can be mounted in a longitudinally displaceable manner on the vehicle structure by a seat console, wherein at least the seat back is adjustable from a sitting position into a resting or lying position, and wherein between the lower seat part and the vehicle structure an energy absorption device is provided. In the event of a collision of the vehicle with an obstacle, the energy absorption device permits a braked relative movement along a braking path between the vehicle seat, which persists in a forwards movement due to inertia, and the vehicle structure, which is braked due to the collision. In the normal state, the vehicle seat is locked relative to the vehicle structure by a locking device and the locking is released in the event of a collision. The locking device is designed such that the locking is released and the longitudinal displaceability of the vehicle seat is enabled before the mass-induced forces of inertia of the body of a person lying on the vehicle seat are completely supported on the seat structure of the lower seat part, and therefore the body only enters into force-transmitting contact with the seat structure when the vehicle seat is already moving forwards relative to the vehicle structure.

A mount assembly for mounting a cabin attendant seat to a support structure may comprise a first strap configured to plastically deform in response to a deflection of the support structure. The first strap may comprise a first perforation, a second perforation, and a third perforation located between the first perforation and the second perforation. The perforations may be configured to allow the strap to plastically deform.

A side airbag apparatus may include: a seat on which a passenger is seated; an inflator mounted on the seat, and configured to jet gas; a cushion inflated by the gas jetted from the inflator, and deployed toward the passenger so as to move the passenger to an inboard side of the vehicle; and a controller configured to operate the inflator to deploy the cushion before the collision of the vehicle, according to driving information of the vehicle, based on a signal of a sensor mounted on the vehicle.

A seat arrangement for a vehicle includes a first seat including an airbag module having an inflatable airbag, and a second seat positionable adjacent to the first seat. The second seat includes a pivotable seatback that is pivotable between an upright use position and a forward pivoted position, and a movement mechanism associated with the seatback for moving the seatback from the use position to the pivoted position. The arrangement further includes a control system configured to actuate the movement mechanism to move the seatback of the second seat from the use position to the pivoted position when the second seat is unoccupied and upon detection of a potential vehicle impact, so that the airbag of the airbag module of the first seat may deploy between an occupant of the first seat and the seatback of the second seat.

A vehicle seat assembly is provided with a seat bottom that is adapted to be mounted to a vehicle floor. A seatback is adapted to be pivotally mounted adjacent to the seat bottom. An actuator is in cooperation with the seat bottom or the seatback. A controller is in electrical communication with the actuator and programmed to receive input indicative of a potential vehicle impact. In response to receiving the input indicative of the potential vehicle impact, the controller outputs a signal to the actuator to tilt the seatback, or to tilt the seat bottom.

A vehicle seat console has at least one vehicle-mounted guiding element, at least one seat-mounted guiding element that runs parallel to the vehicle-mounted guiding element, and a longitudinal adjustment mechanism on which a driving device acts via a transmission mechanism and which is designed to cause a relative adjustment between the vehicle-mounted guiding element and the seat-mounted guiding element. The vehicle seat console is characterized in that the longitudinal adjustment mechanism and/or the transmission mechanism is/are equipped with at least one energy absorption device which is configured to dampen abrupt relative movements between the vehicle-mounted guiding element and the seat-mounted guiding element.