A method of assembling a vehicle seat is provided, comprising: providing a seat back frame; forwardly movably connecting a headrest for supporting a head of a seat occupant to the seat back frame; mounting a rear-end collision detector to the seat back frame at a position behind the seat occupant, operatively connecting the rear-end collision detector to the headrest; disposing a link member at a position lateral to the rear-end collision detector; forming a front extending portion that inwardly extends in a right-to-left direction at a front end of a lateral face of the side frame; and forming a rear extending portion that inwardly extends in the right-to-left direction; wherein a protruding portion is formed from a portion of the lateral face of the side frame that faces at least the part of the bracket, the link support shaft being disposed at a same height as the protruding portion.

The disclosure provides for a system that includes a seat mounted in a vehicle. The seat includes a base, a back support, a hinge, and a seat belt integrated into the seat. The back support is capable of rotating relative to the base and thereby reclining. The hinge is between the base and the back support and is configured to lock the back support in positions in relation to the base. The seat belt has a shoulder portion and a lap portion and is attached to the seat at a shoulder anchor in the back support and a base anchor in the base. When a generated torque, created from a forward force applied by the shoulder portion of the seat belt, exceeds a threshold amount of torque, the hinge is configured to unlock and back support is configured to rotate forward from a reclined position towards an upright position.

An automobile vehicle airbag system includes a vehicle seat having a seat back rotatably connected to a seat base, with the seat base mounted on a seat frame. A seat base cushion is mounted on the seat frame upon which an occupant is seated. A thigh airbag is connected to the seat frame and positioned above the seat frame and below the seat base cushion in a thigh airbag uninflated condition. At least one airbag tether is connected to the seat frame and to the thigh airbag. A lap belt is connected to the vehicle seat and contacts a pelvis of the occupant. When inflated the thigh airbag pushes upward on the seat base cushion forcing the thighs and pelvis of the occupant upward into frictional contact with the lap belt, thereby mitigating against submarining of the pelvis beneath the lap belt.

A vehicle assembly includes a vehicle body and a vehicle seat. The vehicle body includes a frame backing member elongated in a length direction of the vehicle seat. The vehicle seat includes a seat base and a seat back connected to the seat base. The seat back is connected to the frame backing member. A mounting bracket is connected to an upper portion of a seat back frame. An energy attenuating member positioned in a space between the seat back frame and the frame backing member interconnects the mounting bracket and the frame backing member. During a crash event the energy attenuating member is configured to collapse between the seat back and the frame backing member to absorb kinetic energy in the vehicle seat when the seat back is driven toward the frame backing member.

The disclosure provides for a system. The system may include a rotational control system configured to rotate a seat of a vehicle, and one or more computing devices. The one or more computing devices may have one or more processors that are configured to determine that an impact is imminent at a location on the vehicle along a collision axis. A most favorable orientation may be determined by the one or more processors based on the determined location and collision axis. Using the rotational control system, the one or more processors may rotate the seat of the vehicle to the most favorable orientation in order to reduce risks of serious injury to a passenger in the seat caused by the imminent impact. A translational control system may be used by the one or more processors to translate the seat of the vehicle to a position relative to the determined location.

The disclosure provides for a system. The system may include a rotational control system configured to rotate a seat of a vehicle, and one or more computing devices. The one or more computing devices may have one or more processors that are configured to determine that an impact is imminent at a location on the vehicle along a collision axis. A most favorable orientation may be determined by the one or more processors based on the determined location and collision axis. Using the rotational control system, the one or more processors may rotate the seat of the vehicle to the most favorable orientation in order to reduce risks of serious injury to a passenger in the seat caused by the imminent impact. A translational control system may be used by the one or more processors to translate the seat of the vehicle to a position relative to the determined location.

A vehicle seating assembly having a seat cushion and a suspension system disposed proximate an underside of the seat cushion. The suspension system includes a carrier assembly, a displaceable platform, and an attachment member extending between the carrier assembly and the displaceable platform, wherein the attachment member is positionable between the rest position and an extended positon. The displaceable platform is positionable between a design position and a fully deployed position.

A vehicle seat support comprising two rails extending in a longitudinal direction, a central module slidably mounted on the rails and suitable for supporting the vehicle seat, a footrest slidably mounted on the rails in front of the central module and suitable for receiving the feet of an occupant seated on the seat, a first actuation system able to cause the central module to slide along the rails, and a second actuation system able to cause the footrest to slide along the rails independently of the central module.

An occupant protection device, for a vehicle which protects an occupant seated on a seating surface of a seat, includes: a first push-up mechanism which pushes up a waist portion of the occupant by raising a rear portion of the seating surface; a second push-up mechanism which pushes up a thigh portion of the occupant by raising a front portion of the seating surface; and a control unit which controls operations of the first push-up mechanism and the second push-up mechanism. The control unit operates the first push-up mechanism and then operates the second push-up mechanism when an impact applied to the vehicle from the front of the seat is detected or predicted.

A kinetic seat cushion assembly that rotates based on a force applied on an occupant seated therein is provided. The kinetic seat cushion assembly includes a primary seat cushion frame, a secondary seat cushion frame, a seat cushion tilt mechanism coupling the secondary seat cushion frame to the primary seat cushion frame such that the secondary seat cushion frame is movable with respect to the primary seat cushion frame, and a front pivot mechanism that pivotally couples a front portion of the primary seat cushion frame to a front portion of the secondary seat cushion frame.