The present disclosure describes a roof airbag apparatus for mobility which protects the occupant seated in the cabin in such a manner that the roof airbag is deployed downward from the cabin roof, and safely protects the occupant from impact in such a manner that the occupant is securely restrained by the airbag as the deployment shape of the airbag is maintained.

The present disclosure describes a roof airbag apparatus for mobility which protects the occupant seated in the cabin in such a manner that the roof airbag is deployed downward from the cabin roof, and safely protects the occupant from impact in such a manner that the occupant is securely restrained by the airbag as the deployment shape of the airbag is maintained.

A roof airbag system includes a roof airbag, a lifting mechanism, a collision sensor, memory, and a processor coupled to the memory. The roof airbag is provided at a roof portion of a vehicle, receives a supply of gas from an inflator and deploys toward an upper body side of a vehicle occupant sitting on a vehicle seat. The lifting mechanism is provided at a seat cushion side of the vehicle seat and lifts a thigh area of the vehicle occupant. A collision sensor detects a collision of the vehicle. The processor is configured to, when a seat back of the vehicle seat is tilted more than a predetermined angle to the seat rear side and the collision sensor detects a collision of the vehicle, control the lifting mechanism to lift the thigh area of the vehicle occupant and control operation of the inflator to deploy the roof airbag.

A roof airbag system includes a roof airbag, a lifting mechanism, a collision sensor, memory, and a processor coupled to the memory. The roof airbag is provided at a roof portion of a vehicle, receives a supply of gas from an inflator and deploys toward an upper body side of a vehicle occupant sitting on a vehicle seat. The lifting mechanism is provided at a seat cushion side of the vehicle seat and lifts a thigh area of the vehicle occupant. A collision sensor detects a collision of the vehicle. The processor is configured to, when a seat back of the vehicle seat is tilted more than a predetermined angle to the seat rear side and the collision sensor detects a collision of the vehicle, control the lifting mechanism to lift the thigh area of the vehicle occupant and control operation of the inflator to deploy the roof airbag.

A bracket assembly for a vehicle frame includes a trim piece with a high retention clip. The trim piece incudes a deployable portion that is configured to partially deploy in response to a first predetermined force. An inflator tube is concealed by the trim piece and includes an air curtain. A bracket is operably coupled to the trim piece. The bracket has a deformable portion and side portions.

A bracket assembly for a vehicle frame includes a trim piece with a high retention clip. The trim piece incudes a deployable portion that is configured to partially deploy in response to a first predetermined force. An inflator tube is concealed by the trim piece and includes an air curtain. A bracket is operably coupled to the trim piece. The bracket has a deformable portion and side portions.

A roof airbag arrangement includes an airbag, first and second guide rails, at least one first sliding member and at least one second sliding member. The airbag longitudinally extends along a length between first and second longitudinal sides and laterally extending along a width between first and second lateral sides. The first and second guide rails are on laterally opposite sides of the airbag, and define first and second channels, respectively. The at least one first sliding member is mounted within the first guide rail for translation within the first channel. The at least one second sliding member is mounted within the second guide rail for translation within the second channel. First and second pluralities of tethers connect the first lateral side of the airbag with the at least one first sliding member and the second lateral side of the airbag with the at least one second sliding member, respectively.

An apparatus for helping to protect an occupant of a vehicle in the event of a far-side collision in which the vehicle is impacted on a side opposite the seat in which the occupant is seated includes a curtain airbag configured to inflate and deploy from a roof of the vehicle in response to a far-side collision. The curtain airbag has an inflated and deployed condition in which the curtain airbag is positioned inboard of the vehicle occupant.

An apparatus for helping to protect an occupant of a vehicle in the event of a far-side collision in which the vehicle is impacted on a side opposite the seat in which the occupant is seated includes a curtain airbag configured to inflate and deploy from a roof of the vehicle in response to a far-side collision. The curtain airbag has an inflated and deployed condition in which the curtain airbag is positioned inboard of the vehicle occupant.

A guide assembly for a roof airbag arrangement of a vehicle includes a guide member, at least a first sliding member and a locking member. The first sliding member is carried by the guide member and translatable relative to the guide member along a translation axis. The locking member is carried by the guide member and is operable in a first position to permit the first sliding member to translate past the locking member in a first direction and operable in a second position to prevent translation of the first sliding member past the locking member in a second direction. The second direction being opposite to the first direction.